myo-Inositol Transport in Mouse Astroglia-Rich Primary Cultures

Uptake of radiolabeled myo-inositol was studied in astroglia-rich primary cultures derived from neonatal mouse brains. The uptake was saturable in the presence of Na+ with a Km of 25 microM and a Vmax of 60 pmol.min-1.(mg protein)-1, suggesting a high-affinity transport system for myo-inositol in astroglial cells. In addition, a Na(+)-independent, nonsaturable component was found. Carrier-mediated uptake was not inhibited by cytochalasin B (50 microM), but was reduced by depolarizing concentrations of K+ and, to different extents, in the presence of phloretin, ouabain, or amiloride (1 mM each). scyllo-Inositol, glucose, and galactose also reduced myo-inositol uptake; inhibition by the two hexoses was not reversed in the presence of 0.4 mM sorbinil. On the other hand, uptake of 2-deoxyglucose was not inhibited by high concentrations of myo-inositol. Preincubation of the cells with glucose-free or inositol-free medium stimulated uptake of myo-inositol and preincubation with 25 mM glucose in the presence of 0.4 mM sorbinil had no effect on the rate of uptake. The results suggest that myo-inositol is taken up into the astroglial cells by a transport mechanism that is distinct from that of glucose and probably is an active one. Sorbitol pathway activity does not interfere with myo-inositol uptake.     

Trypanosoma cruzi epimastigotes: regulation of myo-inositol transport by effectors of protein kinases A and C

Inositol is the precursor for most Trypanosoma cruzi surface molecules, including phosphoinositides, glycosylinositolphospholipids and glycosylphosphatidylinositol anchors. As the parasite is an inositol auxotroph, the inositol transport system might be a potential target for new trypanocide drugs, as some of its properties are different from its mammalian counterpart. Here, we investigated the modulation exerted by effectors of PKA and PKC on this transport system to comply with the parasite physiology. Pre-incubation of the cells with either dibutyryl-cyclic AMP (25 microM) or forskolin (30 microM) decreased the myo-inositol uptake by half, this effect being reversed by KT5720 (PKA inhibitor). Conversely, pre-incubation of the cells with PMA (2.8 microg/ml) or serum (5%) had a approximately 50% stimulation in myo-inositol uptake, being this effect reversed by staurosporine (0.5 microM) or sphingosine (10 microM). These results allow us to conclude that the myo-inositol transport system in T. cruzi epimastigotes is inhibited by PKA and stimulated by PKC effectors.     

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.     

Glycine transport by cultured human fibroblasts

The transport of glycine was studied in cultured human fibroblasts. The amino acid entered the cell by Na+-dependent and Na+-independent mechanisms. Na+-independent glycine (0.1 mM) transport was less than 10% of total uptake and occurred by a mechanism formally indistinguishable from diffusion. Two distinct routes contributed to Na+-dependent glycine transport. The first route was identified with system A because it was inhibited by MeAIB and underwent adaptive regulation. The second route was identified with system ASC as it was inhibited by L-alanine, but not by MeAIB. Kinetic analysis revealed that the two systems operated glycine transport with the same Km of 1.6 mM, a value unusually high for system ASC.     

Kinetics of myo-inositol transport in corneal endothelial cells: diverse effects of sugars and implications in corneal deutergensence [corrected

Kinetics of myo-inositol (MI) uptake into primary cultures of bovine corneal endothelial cells (CEC) were studied. Confluent corneal endothelial cells accumulated 3H-MI in a time dependent and saturable process. At a narrow range of external concentrations of 3H-MI (4-50 microM), the Na(+)-dependent MI uptake followed saturation kinetics. The apparent Km value was 20 microM with a maximum velocity (Vmax) of 16 pmol/20 min/micrograms DNA. At low external 3H-MI concentrations the uptake was dependent on Na ions, but at higher levels the Na(+)-independent fraction of MI uptake significantly increased. The uptake was sensitive to removal of Ca ions and to the presence of inhibitors such as n-ethyl maleimide, phlorizin, ouabain, and amiloride (an inhibitor of Na+/H+ exchanger). The sensitivity of MI uptake toward inhibitors and ionic changes in the bathing media was reduced as external concentrations of 3H-MI increased. Citrate at 0.5 mM increased the uptake, suggesting involvement of mitochondrial oxidative metabolism in the MI uptake. Percent release of radioactivity by 2 min, after an initial 40-min incubation with 20 microM 3H-MI, was 6.6% +/- 0.8 or 35% +/- 4 when release media contained BSS alone or BSS containing 5 mM nonradioactive MI, respectively. Efflux of radioactivity from the cells also was enhanced when release media contained 40 mM glucose. Glucose and galactose as well as nonmetabolizable glucose analogues, such as 3O-methyl glucose or alpha-methyl glucose, at high concentrations (40 mM), acutely (in the incubation media) or chronically (in the growth media) inhibited MI uptake into CEC, and the extent of inhibition was inversely proportional to the external levels of 3H-MI. However, glucose at lower levels (less than or equal to 10 mM) slightly increased MI uptake. These studies indicated that the uptake of MI into corneal endothelial cells was an Na(+)-dependent active process at a narrow range of external radioactive MI concentrations. Higher levels of MI were taken up by the cells via a passive diffusion mechanism, independent of carrier protein(s). Glucose influenced the uptake of MI in a complex manner. The increased MI efflux by glucose or by MI was perhaps due to the limited capacity of CEC for accumulation or compartmentalization of this or other solutes/osmolytes, a phenomenon that may be related to the role of CEC in maintenance of corneal deutergence. High glucose-induced inhibition of Na(+)-dependent MI uptake may be in part due to glucose regulation of Na+ fluxes and cell volume.(ABSTRACT TRUNCATED AT 400 WORDS)     

Polyamine transport systems in the LLC-PK1 renal epithelial established cell line

LLC-PK1 cells were brought to a quiescent state by treatment with DL-2-difluoromethylornithine (DFMO), a specific inhibitor of L-ornithine decarboxylase (ODC). The inhibition of ODC, which is the key enzyme for polyamine synthesis, strongly reduced the cellular content of putrescine and spermidine. The cells resumed DNA-synthesis followed by mitosis when exogenous putrescine was added. DFMO treatment strongly stimulated the putrescine uptake capability. A kinetic analysis of the initial uptake rates revealed a saturable Na+-dependent and a saturable Na+-independent pathway on top of non-saturable diffusion. The stimulation by DFMO was exclusively due to an effect on the Vmax values of the saturable pathways. The Na+-dependent transporter had a higher affinity for putrescine (apparent Km = 4.7 +/- 0.7 microM) than the Na+-independent transporter (apparent Km = 29.8 +/- 3.5 microM). As a consequence, although the latter transporter had a higher Vmax, the Na+-dependent transport was more important at a physiological putrescine concentration. Putrescine uptake by both transporters was inhibited with similar relative affinities by spermidine, spermine as well as by the antileukemic agent, methylglyoxal bis(guanylhydrazone), but not by amino acids. The activity of the Na+-dependent transporter was very much dependent on SH-group reagents, whereas the Na+-independent transporter was not affected. Both transporters were inhibited by metabolic inhibitors and by ionophores but the Na+-dependent transporter was affected to a greater extent. For both transporters there was a down-regulation in response to exogenous putrescine. This suggests that the polyamine transporters in LLC-PK1 are adaptively regulated and may contribute to the regulation of the cellular polyamine level and cellular proliferation.     

Pharmacological characterization of dopamine transport in cultured rat astrocytes.

The effects of GBR-12909 (selective DA uptake inhibitor), zimelidine (selective 5-HT uptake inhibitor) and nisoxetine (selective NE uptake inhibitor) on the uptake of 30 nM [3H]DA into cultured rat astrocytes were examined. [3H]DA uptake was inhibited by approximately 50% by GBR-12909 or zimelidine in a concentration-dependent manner (100 nM to approximately 10 microM). Furthermore, the inhibition curves of GBR-12909 were biphasic, and uptake was completely inhibited by a high concentration of GBR-12909 (100 microM). [3H]DA uptake was also inhibited by approximately 50% by nisoxetine in a concentration-dependent manner (0.1 to approximately 100 nM), and nisoxetine was more potent than GBR-12909 or zimelidine. The inhibitory potencies were in the order nisoxetine > GBR-12909 > zimelidine. The uptake of [3H]DA under Na+-free conditions was approximately 50% of that under normal conditions. Thus, DA was taken up by both Na+-dependent and Na+-independent mechanisms. Nisoxetine (100 nM), zimelidine (100 microM) and GBR-12909 (10 microM) inhibited [3H]DA uptake into astrocytes only in the presence of Na+. On the other hand, this uptake was completely inhibited by a high concentration of GBR-12909 (100 microM) in the absence of Na+. The present data suggest that the Na+-dependent uptake of [3H]DA in cultured rat astrocytes may occur in the NE uptake system. Furthermore, astrocytes express the extraneuronal monoamine transporter (uptake2), which is an Na+-independent system, and this transporter is involved in the inactivation of centrally released DA.     

Characterization of neutral and cationic amino acid transport in Xenopus oocytes

Amino acid transport was characterized in stage 6 Xenopus laevis oocytes. Most amino acids were taken up by the oocytes by way of both Na+-dependent and saturable Na+-independent processes. Na+-dependent transport of 2-aminoisobutyric acid (AIB) was insensitive to cis- or trans-inhibition by the System A-defining substrate 2-(methylamino)-isobutyric acid (MeAIB), although threonine, leucine, and histidine were found to be effective inhibitors, eliminating greater than 80% of Na+-dependent AIB uptake. Lack of inhibition by arginine eliminates possible mediation by System Bo,+ and suggests uptake by System ASC. The Na+-dependent transport of characteristic System ASC substrates such as alanine, serine, cysteine, and threonine was also insensitive to excess MeAIB. Evidence to support the presence of System Bo,+ was obtained through inhibition analysis of Na+-dependent arginine transport as well arginine inhibition of Na+-dependent threonine uptake. The Na+-independent transport of leucine was subject to trans-stimulation and was inhibited by the presence of excess phenylalanine, histidine, and, to a lesser extent, 2-amino-(2,2,1)-bicycloheptane-2-carboxylic acid (BCH). These observations are consistent with mediation by System L. The characteristics of Na+-independent uptake of threonine are not consistent with assignment to System L, and appear to be reflective of Systems asc and bo,+. In its charged state, histidine appears to be transported by a carrier similar in its specificity to System y+, but is taken up by System L when present as a zwitterion.     

Cation and harmaline interactions with Na(+)-independent dibasic amino acid transport system y+ in human erythrocytes and in erythrocytes from a primitive vertebrate the pacific hagfish (Eptatretus stouti).

Transport systems y+, asc and ASC exhibit dual interactions with dibasic and neutral amino acids. For conventional Na(+)-dependent neutral amino acid system ASC, side chain amino and guanido groups bind to the Na+ site on the transporter. The topographically equivalent recognition site on related system asc binds harmaline (a Na(+)-site inhibitor) with the same affinity as asc (apparent Ki range 1-4 mM), but exhibits no detectable affinity for Ha. Although also classified as Na(+)-independent, dibasic amino acid transport system y+ accepts neutral amino acids when Na+ or another acceptable cation is also present. This latter observation implies that the y+ translocation site binds Na+ and suggests possible functional and structural similarities with ASC/asc. In the present series of experiments with human erythrocytes, system y(+)-mediated lysine uptake (5 microM, 20 degrees C) was found to be 3-fold higher in isotonic sucrose medium than in normal 150 mM NaCl medium. This difference was not a secondary consequence of changes in membrane potential, but resulted from Na+ functioning as a competitive inhibitor of transport. Apparent Km and Vmax values for lysine transport at 20 degrees C were 15.2 microM and 183 mumol/l cells per h, respectively, in sucrose medium and 59.4 microM and 228 mumol/l cells per h in Na+ medium. Similar results were obtained with y+ in erythrocytes of a primitive vertebrate, the Pacific hagfish (Eptatretus stouti), indicating that Na(+)-inhibition is a general property of this class of amino acid transporter. At a permeant concentration of 5 microM, the IC50 value for Na(+)-inhibition of lysine uptake by human erythrocytes was 27 mM. Other inorganic and organic cations, including K+ and guanidinium+, also inhibited transport. In parallel with its actions on ASC/asc harmaline competitively inhibited lysine uptake by human cells in sucrose medium. As predicted from mutually competitive binding to the y+ translocation site, the presence of 150 mM Na+ increased the harmaline inhibition constant (Ki) from 0.23 mM in sucrose medium to 0.75 mM in NaCl medium. We interpret these observations as further evidence that y+, asc and ASC represent a family of closely related transporters with a common evolutionary origin.     

L-Fucose Is a Potent Inhibitor of myo-Inositol Transport and Metabolism in Cultured Neuroblastoma Cells

It has been proposed that abnormal myo-inositol metabolism may be a factor in the development of diabetic complications. Studies with animal models of diabetes and cultured cells have suggested that hyperglycemia by an unknown mechanism may alter myo-inositol metabolism and content. Recently, we have shown that L-fucose, a 6-deoxy sugar whose content has been reported to be increased in diabetes, is a potent inhibitor of myo-inositol transport. To examine the effect of L-fucose on myo-inositol metabolism, neuroblastoma cells were cultured in medium supplemented with L-fucose. L-Fucose is a competitive inhibitor of Na(+)-dependent, high-affinity myo-inositol transport. The Ki for inhibition of myo-inositol transport by L-fucose is about 3 mM. L-Fucose is taken up and accumulates in neuroblastoma cells. The uptake of L-fucose is inhibited by Na+ depletion, D-glucose, glucose analogues, phloridzin, and cytochalasin B. In contrast, neither myo-inositol nor L-glucose inhibits L-fucose uptake. Chronic exposure of neuroblastoma cells to 1-30 mM L-fucose causes a decrease in myo-inositol accumulation and incorporation into inositol phospholipids, intracellular free myo-inositol content, and phosphatidylinositol levels. Na+,K(+)-ATPase transport activity is decreased by about 15% by acute or chronic exposure of neuroblastoma cells to L-fucose. Similar defects occur when neuroblastoma cells are exposed chronically to 30 mM glucose. Cell myo-inositol metabolism and Na+/K(+)-pump activity are maintained when 250 microM myo-inositol is added to the L-fucose-supplemented medium. Unlike the effect of chronic exposure of neuroblastoma cells to medium containing 30 mM glucose, the resting membrane potential of neuroblastoma cells is not altered by chronic exposure of the cells to 30 mM L-fucose. The effect of L-fucose on cultured neuroblastoma cell properties occurs at concentrations of L-fucose which may exist in the diabetic milieu. These data suggest that increased concentrations of L-fucose may have a role in myo-inositol-related defects in mammalian cells.     

Characteristics of L-glutamine transport during Caco-2 cell differentiation

Glutamine is the main fuel of intestinal epithelial cells, as well as a precursor for the intense nucleotide biosynthesis which arises with the rapid turnover of enterocytes. In order to determine whether glutamine uptake may vary as a function of metabolic demand, glutamine transport across the brush-border membrane of differentiating Caco-2 cells has been investigated. The uptake of L-[(3)H]glutamine was measured between day 7 and day 21 post-seeding. Kinetic analysis with glutamine concentrations ranging from 6.25 microM to 12.8 mM revealed the involvement of high affinity Na(+)-dependent (K(t)=110 microM) and low affinity Na(+)-independent (K(t)=900 microM) transport components at day 7. Both components were partially inhibited by L-lysine in a competitive fashion, suggesting that four different systems were responsible for glutamine uptake: B(0), B(0,+), b(0,+) and L. All four systems were present during the differentiation process, with systems L and B(0) being responsible for up to 80% of glutamine uptake. Caco-2 cell differentiation was associated with a marked decrease in L-glutamine uptake, which affected both the Na(+)-dependent and the Na(+)-independent components. In contrast to glucose uptake, the development of L-glutamine uptake across the brush-border membrane of Caco-2 cells may reflect an adjustment to cell metabolic demand rather than the progressive appearance of a vectorial transport process.     

Functional and molecular identification of sodium-coupled dicarboxylate transporters in rat primary cultured cerebrocortical astrocytes and neurons

Na+-coupled carboxylate transporters (NaCs) mediate the uptake of tricarboxylic acid cycle intermediates in mammalian tissues. Of these transporters, NaC3 (formerly known as Na+-coupled dicarboxylate transporter 3, NaDC3/SDCT2) and NaC2 (formerly known as Na+-coupled citrate transporter, NaCT) have been shown to be expressed in brain. There is, however, little information available on the precise distribution and function of both transporters in the CNS. In the present study, we investigated the functional characteristics of Na+-dependent succinate and citrate transport in primary cultures of astrocytes and neurons from rat cerebral cortex. Uptake of succinate was Na+ dependent, Li+ sensitive and saturable with a Michaelis constant (Kt) value of 28.4 microM in rat astrocytes. Na+ activation kinetics revealed that the Na+ to succinate stoichiometry was 3:1 and the concentration of Na+ necessary for half-maximal transport was 53 mM. Although uptake of citrate in astrocytes was also Na+ dependent and saturable, its Kt value was significantly higher (approximately 1.2 mM) than that of succinate. Unlabeled succinate (2 mM) inhibited Na+-dependent [14C]succinate (18 microM) and [14C]citrate (4.5 microM) transport completely, whereas unlabeled citrate inhibited Na+-dependent [14C]succinate uptake more weakly. Interestingly, N-acetyl-L-aspartate, which is the second most abundant amino acid in the nervous system, also completely inhibited Na+-dependent succinate transport in rat astrocytes. The inhibition constant (Ki) for the inhibition of [14C]succinate uptake by unlabeled succinate, N-acetyl-L-aspartate and citrate was 15.9, 155 and 764 microM respectively. In primary cultures of neurons, uptake of citrate was also Na+ dependent and saturable with a Kt value of 16.2 microM, which was different from that observed in astrocytes, suggesting that different Na+-dependent citrate transport systems are expressed in neurons and astrocytes. RT-PCR and immunocytochemistry revealed that NaC3 and NaC2 are expressed in cerebrocortical astrocytes and neurons respectively. These results are in good agreement with our previous reports on the brain distribution pattern of NaC2 and NaC3 mRNA using in situ hybridization. This is the first report of the differential expression of different NaCs in astrocytes and neurons. These transporters might play important roles in the trafficking of tricarboxylic acid cycle intermediates and related metabolites between glia and neurons.     

alpha-aminoisobutyrate transport into cells from R3230AC mammary adenocarcinoma. Evidence for sodium ion-dependent and -independent carrier-mediated entry and effects of diabetes.

In the presence of Na+, alpha-aminoisobutyrate was transported by saturable and non-saturable processes into R3230AC mammary tumour cells isolated by enzymic treatment. Eadie-Hofstee analysis for the saturable process gave a curvilinear plot, suggesting that transport occurred by more than one carrier. In the absence of Na+, alpha-aminoisobutyrate was also transported by both saturable and non-saturable processes. This Na+-independent saturable process gave a linear plot according to Eadie-Hofstee analysis: V, 708 +/- 105 pmol/min per 5 X 10(6) cells; Km, 0.36 +/- 0.33 mM (mean +/- S.E.M.). Subtracting alpha-aminoisobutyrate entry in the absence of Na+ from total alpha-aminoisobutyrate uptake (in the presence of Na+) showed the presence of another saturable process (Na+-dependent), accounting for 75% of total alpha-aminoisobutyrate uptake. This component gave a linear Eadie-Hofstee plot: V, 2086 +/- 213; Km, 1.75 +/- 0.16 alpha-(Methylamino)isobutyrate, a substrate specifically taken up by the A system, inhibited 80% of alpha-aminoisobutyrate entry. The presence of both alhpa-(methylamino)isobutyrate and phenylalanine inhibited alpha-aminoisobutyrate entry completely. 2-Aminobicyclo[2.2.1]heptane-2-carboxylate, an analogue specifically taken up by the Na+-independent system, inhibited completely the Na+-independent entry of alpha-aminoisobutyrate. In the presence of Na+, the distribution ratio, which is defined as the amino acid concentration in the intracellular space divided by that in the incubation medium for alpha-aminoisobutyrate, at 90 min was 19, and in the absence of Na+ at 60 min was 5. These concentrative processes were sensitive to the metabolic inhibitor pentachlorophenol. The Na+-dependent, but not the Na+-independent, alpha-aminoisobutyrate uptake was increased in cells from diabetic rats. This was primarily due to an increase in the V for the Na+-dependent component (164%) with no effect on the Km. We conclude, therefore, that alpha-aminoisobutyrate entry into cells from this mammary tumour is mediated by two transport systems, one Na+-dependent and another Na+-independent. Furthermore, the Na+-dependent component of alpha-aminoisobutyrate is sensitive to alterations of insulin in vivo.     

Characterization of Xylamine Binding to Proteins of PC12 Pheochromocytoma Cells

PC12 pheochromocytoma cells take up 3,4-dihydroxyphenylethylamine (dopamine) and norepinephrine by a Na+-dependent, cocaine-sensitive system. The kinetics suggest that the same transporter functions for both substrates. Xylamine, a nitrogen mustard that blocks catecholamine uptake into neurons, irreversibly inhibited norepinephrine uptake into PC12 (IC50 = 15 microM). Pretreatment with 10 microM xylamine did not inhibit norepinephrine transport if 10 microM cocaine or 100 microM norepinephrine was also present during the pretreatment period or if Na+ was absent. These results indicate that xylamine must interact with the norepinephrine transporter to inhibit norepinephrine uptake. PC12 accumulated [3H]xylamine; this uptake had Na+-dependent and Na+-independent components. The Na+-dependent uptake was saturable (Km = 13 microM), and it was inhibited by cocaine (IC50 = 0.6 microM), desipramine (IC50 less than 1 nM), and norepinephrine (IC50 = 1 microM). Several proteins became prominently labeled when intact PC12 cells were incubated with [3H]xylamine; these proteins were enriched in a plasma membrane fraction and have molecular weights of 17,000, 24,000, 31,000, 33,000, 41,000, 42,000, 52,000, and 80,000. Other proteins were labeled less prominently. The labeling of all proteins was markedly decreased when the incubation with [3H]xylamine occurred in the presence of cocaine, desipramine, gramicidin D, or in a Na+-free buffer. These results indicate that xylamine must be transported into the cells for covalent binding to proteins to occur. [3H]Xylamine labeled essentially the same proteins when incubated with cell homogenates, but competition experiments with bretylium, desipramine, and cocaine failed to reveal which of the [3H]xylamine-labeled proteins is associated with the norepinephrine transporter.     

Sodium-dependent nucleoside transport in mouse leukemia L1210 cells

Nucleoside permeation in L1210/AM cells is mediated by (a) equilibrative (facilitated diffusion) transporters of two types and by (b) a concentrative Na(+)-dependent transport system of low sensitivity to nitrobenzylthioinosine and dipyridamole, classical inhibitors of equilibrative nucleoside transport. In medium containing 10 microM dipyridamole and 20 microM adenosine, the equilibrative nucleoside transport systems of L1210/AM cells were substantially inhibited and the unimpaired activity of the Na(+)-dependent nucleoside transport system resulted in the cellular accumulation of free adenosine to 86 microM in 5 min, a concentration three times greater than the steady-state levels of adenosine achieved without dipyridamole. Uphill adenosine transport was not observed when extracellular Na+ was replaced by Li+, K+, Cs+, or N-methyl-D-glucammonium ions, or after treatment of the cells with nystatin, a Na+ ionophore. These findings show that concentrative nucleoside transport activity in L1210/AM cells required an inward transmembrane Na+ gradient. Treatment of cells in sodium medium with 2 mM furosemide in the absence or presence of 2 mM ouabain inhibited Na(+)-dependent adenosine transport by 50 and 75%, respectively. However, because treatment of cells with either agent in Na(+)-free medium decreased adenosine transport by only 25%, part of this inhibition may be secondary to the effects of furosemide and ouabain on the ionic content of the cells. Substitution of extracellular Cl- by SO4(-2) or SCN- had no effect on the concentrative influx of adenosine.     

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.     

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).     

Ethoxyzolamide Differentially Inhibits CO2 Uptake and Na+-Independent and Na+-Dependent HCO3- Uptake in the Cyanobacterium Synechococcus sp. UTEX 625

The effects of ethoxyzolamide (EZ), a carbonic anhydrase inhibitor, on the active CO2 and Na+-independent and Na+-dependent HCO3- transport systems of the unicellular cyanobacterium Synechococcus sp. UTEX 625 were examined. Measurements of transport and accumulation using radiochemical, fluorometric, and mass spectrometric assays indicated that active CO2 transport and active Na+-independent HCO3- transport were inhibited by EZ. However, Na+-independent HCO3- transport was about 1 order of magnitude more sensitive to EZ inhibition than was CO2 transport (50% inhibition = 12 [mu]M versus 80 [mu]M). The data suggest that both the active CO2 (G.D. Price, M.R. Badger [1989] Plant Physiol 89: 37-43) and the Na+ -independent HCO3 - transport systems possessed carbonic anhydrase-like activity as part of their mechanism of action. In contrast, Na+-dependent HCO3- transport was only partially (50% inhibition = 230 [mu]M) and noncompetitively inhibited by EZ. The collective evidence suggested that EZ inhibition of Na+ -dependent HCO3- transport was an indirect consequence of the action of EZ on the CO2 transport system, rather than a direct effect on HCO3- transport. A model is presented in which the core of the inorganic carbon translocating system is formed by Na+-dependent HCO3- transport and the CO2 transport system. It is argued that the Na+-independent HCO3 - utilizing system was not directly involved in translocation, but converted HCO3- to CO2 for use in CO2 transport.     

Characterization of a Pi transport system in cartilage matrix vesicles. Potential role in the calcification process.

The mechanisms by which calcium (Ca2+) and inorganic phosphate (Pi) accumulate into matrix vesicles (MV) have not been elucidated. In the present study the characteristics of Pi uptake into MV isolated from mildly rachitic chicken growth plate cartilage have been investigated. The results indicate that Pi accumulates into MV mainly via a Na(+)-dependent Pi transport system. In the absence of NaCl in the extravesicular medium, Pi uptake was a nonsaturable process. In the presence of 150 mM NaCl, the initial rate of Pi uptake was 4.38 +/- 1.02-fold higher than with 150 mM choline chloride (mean +/- S.E., n = 8, p less than 0.005). Other cations showed partial activity to drive Pi into MV as compared to Na+:Li+ (64.4%) greater than K+ (39.8%) greater than choline (39.0%) greater than tetramethylammonium (30.0%) greater than N-methylglucamine (26.3%). Na(+)-dependent Pi transport activity displayed saturability towards increasing extra-vesicular concentrations of Na+ and Pi. The apparent Km for Pi was 0.68 +/- 0.16 mM. The Na+ concentration producing half-maximum Pi transport activity was 106.2 +/- 11.0 mM. Kinetic analysis suggests that Na+ interacts with the Pi carrier with a stoichiometry of more than one Na+ ion with one Pi molecule. In MV isolated from normal chicken growth plate cartilage, this Na(+)-dependent Pi transport system was barely expressed. In contrast to the effect on Pi uptake by MV, the activity of alkaline phosphatase was not changed when NaCl was substituted for choline chloride in the assay medium. In addition to this observation which suggests that this enzyme is not related to the Pi transport activity described in this study, levamisole, which inhibited alkaline phosphatase activity did not affect the Na(+)-dependent uptake of Pi. Both arsenate and phosphonoformic acid, two inhibitors of the epithelial Na(+)-dependent Pi transport systems, were active inhibitors of the Na(+)-dependent Pi uptake by MV with a higher potency for phosphonoformic acid. Associated with the expression of a facilitated Na(+)-coupled Pi transport in MV, in vitro calcification assessed by 45Ca2+ uptake also showed a marked dependence on extravesicular sodium. This relationship was markedly attenuated in MV isolated from normal chicken growth plate cartilage expressing a weak Na(+)-facilitated Pi transport activity. In conclusion, a saturable Na(+)-dependent Pi carrier has been characterized which facilitates Pi transport in MV. Its potential role for Ca-Pi accumulation into MV and subsequent development of vesicular calcification followed by mineralization of the osteogenic matrix is proposed and remains to be further investigated.     

Monensin Inhibition of Na+-Dependent HCO3- Transport Distinguishes It from Na+-Independent HCO3- Transport and Provides Evidence for Na+/HCO3- Symport in the Cyanobacterium Synechococcus UTEX 625

The effect of monensin, an ionophore that mediates Na+/H+ exchange, on the activity of the inorganic carbon transport systems of the cyanobacterium Synechococcus UTEX 625 was investigated using transport assays based on the measurement of chlorophyll a fluorescence emission or 14C uptake. In Synechococcus cells grown in standing culture at about 20 [mu]M CO2 + HCO3-, 50 [mu]M monensin transiently inhibited active CO2 and Na+-independent HCO3- transport, intracellular CO2 and HCO3- accumulation, and photosynthesis in the presence but not in the absence of 25 mM Na+. These activities returned to near-normal levels within 15 min. Transient inhibition was attributed to monensin-mediated intracellular alkalinization, whereas recovery may have been facilitated by cellular mechanisms involved in pH homeostasis or by monensin-mediated H+ uptake with concomitant K+ efflux. In air-grown cells grown at 200 [mu]M CO2 + HCO3- and standing culture cells, Na+-dependent HCO3- transport, intracellular HCO3- accumulation, and photosynthesis were also inhibited by monensin, but there was little recovery in activity over time. However, normal photosynthetic activity could be restored to air-grown cells by the addition of carbonic anhydrase, which increased the rate of CO2 supply to the cells. This observation indicated that of all the processes required to support photosynthesis only Na+-dependent HCO3- transport was significantly inhibited by monensin. Monensin-mediated dissipation of the Na+ chemical gradient between the medium and the cells largely accounted for the decline in the HCO3- accumulation ratio from 751 to 55. The two HCO3- transport systems were further distinguished in that Na+-dependent HCO3- transport was inhibited by Li+, whereas Na+-independent HCO3- transport was not. It is suggested that Na+-dependent HCO3- transport involves an Na+/HCO3- symport mechanism that is energized by the Na+ electrochemical potential.