Inhibitory effect of diethyl pyrocarbonate on the H+/organic cation antiport system in rat renal brush-border membranes

We examined the effect of diethyl pyrocarbonate (DEPC), a histidine-specific reagent, on the H+/organic cation antiport system in brush-border membrane vesicles isolated from the rat renal cortex. Pretreatment of membrane vesicles with DEPC resulted in the inhibition of tetraethylammonium transport. This inhibition was reversed by subsequent treatment with hydroxylamine, but not with dithiotreitol. In contrast, the uptake of p-aminohippurate, a typical organic anion, was not inhibited by DEPC pretreatment. In the absence of an H+ gradient, pretreatment with DEPC inhibited the uptake of tetraethylammonium at pH 6.0-7.0, but not at pH 7.5. The Vmax value of tetraethylammonium uptake at pH 7.0 was decreased without any change in the Km value, but the kinetic parameters at pH 7.5 were unchanged. Unlabeled tetraethylamonium did not protect against the inhibition by DEPC. These results suggest that histidine residues in the organic cation carrier are essential for transport at acidic and neutral pH values, but not at alkaline pH values, and that histidine residues play an important role as regulatory sites in the H+/organic cation antiport system rather than as binding sites for organic cations.     

An essential histidine residue in GTP binding domain of bovine brain glutamate dehydrogenase isoproteins

Greater than 90% of the original activity of the enzymes remained after modification of histidine residues of glutamate dehydrogenase (GDH) isoproteins from bovine brains with diethyl pyrocarbonate (DEPC). This suggests that the DEPC modified histidine residues are not critically involved in the catalysis of the GDH isoproteins. The influence of DEPC modified histidine residue(s) on binding of GTP to GDH isoproteins was investigated by protection studies. These studies showed that inhibition of GDH isoproteins by GTP was protected by preincubation of GDH isoproteins with DEPC. The amount of protection was dependent on the concentration of DEPC. The GTP inhibition was fully protected by preincubation of GDH isoproteins with DEPC at saturating concentrations. These results indicate that the histidine residues may play an important role in the GTP binding on GDH isoproteins. Spectrophotometric studies showed that three histidine residues per enzyme subunit were able to react with DEPC in the absence of GTP, whereas two histidine residues per enzyme subunit interacted with DEPC when the enzymes were preincubated with GTP. These results indicate that one of the histidine residues is involved in the GTP binding domain of GDH isoproteins. The quantitative affinity chromatographic studies showed that the influence of GTP on the binding of GDH isoproteins to DEPC-Sepharose was significantly distinct for the two GDH isoproteins. GDH I was more sensitively affected by GTP than GDH II in the binding affinity for DEPC-Sepharose. ADP, another well-known allosteric regulator, showed no significant changes in the interaction of DEPC with GDH isoproteins.     

Sugar uptake into brush border vesicles from dog kidney. II. Kinetics

The kinetics of D-glucose transport over the concentration range 0.07--20 mM have been investigated in a vesiculated membrane preparation from dog kidney cortex. 1. A sodium-dependent and a sodium-independent component of D-glucose uptake are observed. The sodium-dependent component is phlorizin sensitive (KI approximately 0.6 micron) and electrogenic. 2. The sodium-dependent component of D-glucose uptake yields non-linear Eadie-Hofstee plots consistent with the presence of high (GH) and low (GL) affinity sites (KH approximately 0.2 mM, KL approximately 4.5 mM, VL/VH approximately 7 at pH 7.4, 25 degrees C, 100 mM NaC1 gradient). Alternative explanations are cooperative effects of non-Michaelis-Menten kinetics. 3. The initial uptake of D-glucose increases as the intravesicular membrane potential become more negative but the numerical values of KH and KL show little, if any, change. 4. alpha-Methyl-D-glucoside transport is also sodium dependent and phlorizin sensitive (KI approximately 1.9 micron). 5. In contrast to the results for D-glucose, the sodium-dependent component of alpha-methyl-D-glucoside uptake exhibits a nearly linear Eadie-Hofstee plot consistent with a single carrier site with Km approximately 1.9 mM and Vmax approximately 27 nmol/min per mg protein at pH 7.4, 25 degrees C, 100 mM NaCl gradient. 6. The kinetics of D-glucose transport in newborn dog kidney are similar to those in the adult except that the low affinity (GL) system appears to be less well developed.     

Brush border membrane proteins in experimental Fanconi's syndrome induced by 4-pentenoate and maleate.

Fanconi's syndrome was investigated using brush border membrane (BBM) vesicles isolated from dog kidney. Sodium-dependent uptake of glucose, phosphate, and amino acids and protein phosphorylation were studied in BBM isolated from normal and from 4-pentenoate- and maleate-treated animals. The time course of D-glucose and phosphate uptake, in BBM vesicles, remained unchanged, indicating that both treatments had no effect on carrier properties, and that permeabilities to these substrates and to sodium were not modified. Furthermore, sodium-dependent transport of alanine, phenylalanine, proline, glycine, and glutamate into vesicles remained unaltered by either treatment. 4-Pentenoate treatment caused modifications of the phosphorylation pattern of BBM proteins: the phosphorylation of two proteins (61 and 74 kDa) was increased and that of two others (48 and 53 kDa) was decreased. Maleate treatment caused an increase in the phosphorylation for the same 61-kDa protein, which was also affected by 4-pentenoate treatment, suggesting that phosphorylation of this protein could be related to a mechanism involved in both 4-pentenoate- and maleate-induced Fanconi's syndrome. These changes were also observed in the presence of sodium fluoride and L-bromotetramisole, indicating that the modification of phosphorylation was not due to a difference in phosphatase activities. These results suggest that Fanconi's syndrome induced by 4-pentenoate or maleate is not caused by an inhibition of BBM Na(+)-dependent transport systems. Our results also suggest that protein phosphorylation may play an important role in the molecular defect involved in Fanconi's syndrome.     

Involvement of histidine residues and sulfhydryl groups in the function of the biotin transport carrier of rabbit intestinal brush-border membrane.

Possible involvement of histidine residues and sulfhydryl groups in the function of the intestinal brush-border membrane (BBM) transporter of biotin was investigated. This was done by examining the effects of pretreatment of BBM vesicle (BBMV) isolated from rabbit intestine with the histidine-specific reagent diethyl pyrocarbonate (DEPC) and the sulfhydryl group-specific reagents p-chloromercuribenzenesulfonic acid (p-CMBS) and 7-chloro-4-nitrobenz-2-oxa-1,3-diazole (NBD-Cl) on carrier-mediated biotin transport. Pretreatment of BBMV with DEPC caused significant inhibition in the initial rate of biotin transport without affecting the substrate uptake at equilibrium. Addition of biotin plus Na+ to vesicle suspensions prior to treatment with DEPC provided significant protection to biotin transport. Treatment of DEPC-pretreated vesicles with the reducing agents dithiothreitol and 2,3-dimercaptopropanol failed to reverse the inhibitory effect of DEPC on biotin transport. The inhibitory effect of DEPC was found to be mediated through a marked decrease in the number of the functional biotin transport carriers with no change in their affinity, as indicated by the severe inhibition in the Vmax but not the apparent Km of the biotin transport process, respectively. Pretreatment of BBMV with p-CMBS and NBD-Cl also caused significant inhibition in the initial rate of biotin transport without affecting the substrate uptake at equilibrium. Addition of biotin plus Na+ to vesicle suspensions prior to treatment with p-CMBS (or NBD-Cl) failed to protect biotin transport from inhibition. On the other hand, treatment of vesicles pretreated with p-CMBS (or NBD-Cl) with the reducing agents dithiothreitol and mercaptoethanol caused significant reversal in the inhibition of biotin transport. The inhibitory effects of p-CMBS (and NBD-Cl) on biotin transport was also found to be mediated through inhibition in the Vmax, but not the apparent Km, of biotin transport process. These results indicate the involvement of histidine residues and sulfhydryl groups in the normal function of the biotin transport system of rabbit intestinal BBM. Furthermore, the results also suggest that the histidine residues are probably located at (or near) the substrate-binding site while the sulfhydryl groups are located at a site other than the substrate binding region.     

Sodium-dependent phosphate transport by apical membrane vesicles from a cultured renal epithelial cell line (LLC-PK1)

Apical membrane vesicles were prepared from confluent monolayers of LLC-PK1 cells grown upon microcarrier beads. The final membrane preparation, obtained by a modified divalent cation precipitation technique, was enriched in alkaline phosphatase, leucine aminopeptidase and trehalase (8-fold compared to the initial homogenate). Analysis of phosphate uptake into the vesicles identified a specific sodium-dependent pathway. Lithium and other cations were unable to replace sodium. At 100 mmol/l sodium and pH 7.4, an apparent Km for phosphate of 99 +/- 19 mumol/l and an apparent Ki for arsenate of 1.9 mmol/l were found. Analysis of the sodium activation of phosphate uptake gave an apparent Km for sodium of 32 +/- 12 mmol/l and suggested the involvement of two sodium ions in the transport mechanism. Sodium modified the apparent Km of the transport system for phosphate. The rate of sodium-dependent phosphate uptake was higher at pH 6.4 than at pH 7.4. At both pH values, an inside negative membrane potential (potassium gradient plus valinomycin) had no stimulatory effect on the rate of the sodium-dependent component of phosphate uptake. It is concluded that the apical membrane of LLC-PK1 cells contains a sodium-phosphate cotransport system with a stoichiometry of 2 sodium ions: 1 phosphate anion.     

Effect of parathyroid hormone and dietary phosphate on phosphate transport in renal outer cortical and outer medullary brush-border membrane vesicles

Two distinctive sodium-dependent phosphate transport systems have been identified in early and late proximal tubules; a high-capacity process located only in outer cortical tissue, and a high affinity present in both outer cortical and outer medullary brush-border membranes (Km 0.1-0.25 mM). A third, sodium-independent, pH gradient-stimulated system (Vmax 4.7 +/- 0.3 nmol.mg-1.min-1, Km 0.15 +/- 0.002 mM) is present in the outer medulla, but absent in outer cortex. Brush-border vesicles were prepared from outer cortical and outer medullary tissue of pigs maintained on low (less than 0.05%), normal (0.4%), or high (4%) phosphate diets. Sodium-dependent phosphate uptake of the high-capacity system decreased (Vmax, 9.4 to 2.2 nmol.mg-1.min-1) from low to high phosphate diet, whereas uptake rates decreased about 50% in the high-affinity system. There were no changes in the respective Km values. The pH gradient-stimulated uptake also decreased (Vmax, 6.9 to 3.0 nmol.mg-1.min-1) with no change in mean Km value (0.15 +/- 0.001 mM) with dietary manipulation. Administration of 1 U parathyroid hormone prior to study resulted in a decrease in sodium-dependent uptake by 40-50% and in pH-dependent uptake (36%) with no change in the respective Km values. In conclusion, the antecedent dietary phosphate intake and parathyroid hormone administration appropriately alters phosphate uptake across the brush-border membrane of all three systems, sodium-dependent and pH gradient-stimulated phosphate transport.     

Influence of amino acid side-chain modification on the uptake system for beta-lactam antibiotics and dipeptides from rabbit small intestine

The influence of chemical modification of functional amino acid side-chains in proteins on the H(+)-dependent uptake system for orally active alpha-amino-beta-lactam antibiotics and small peptides was investigated in brush-border membrane vesicles from rabbit small intestine. Neither a modification of cysteine residues by HgCl2, NEM, DTNB or PHMB and of vicinal thiol groups by PAO nor a modification of disulfide bonds by DTT showed any inhibition on the uptake of cephalexin, a substrate of the intestinal peptide transporter. In contrast, the Na(+)-dependent uptake systems for D-glucose and L-alanine were greatly inhibited by the thiol-modifying agents. With reagents for hydroxyl groups, carboxyl groups or arginine the transport activity for beta-lactam antibiotics also remained unchanged, whereas the uptake of D-glucose and L-alanine was inhibited by the carboxyl specific reagent DCCD. A modification of tyrosine residues with N-acetylimidazole inhibited the peptide transport system and did not affect the uptake systems for D-glucose and L-alanine. The involvement of histidine residues in the transport of orally active alpha-amino-beta-lactam antibiotics and small peptides (Kramer, W. et al. (1988) Biochim. Biophys. Acta 943, 288-296) was further substantiated by photoaffinity labeling studies using a new photoreactive derivative of the orally active cephalosporin cephalexin, 3-[phenyl-4-3H]azidocephalexin, which still carries the alpha-amino group being essential for oral activity. 3-Azidocephalexin competitively inhibited the uptake of cephalexin into brush-border membrane vesicles. The photoaffinity labeling of the 127 kDa binding protein for beta-lactam antibiotics with this photoprobe was decreased by the presence of cephalexin, benzylpenicillin or dipeptides. A modification of histidine residues in brush-border membrane vesicles with DEP led to a decreased labeling of the putative peptide transporter of Mr 127,000 compared to controls. This indicates a decrease in the affinity of the peptide transporter for alpha-amino-beta-lactam antibiotics by modification of histidine residues. The data presented demonstrate an involvement of tyrosine and histidine residues in the transport of orally active alpha-amino-beta-lactam antibiotics across the enterocyte brush-border membrane.     

Modification of system A amino acid carrier by diethyl pyrocarbonate

Sodium-dependent alanine transport in plasma membrane vesicles from rat liver was inactivated in a time- and concentration-dependent fashion by prior treatment of membranes with the acylating reagent diethyl pyrocarbonate (DEPC). Both components of Na+/alanine cotransport (systems A and ASC) were inhibited. Exposure of vesicles to p-bromophenacyl bromide and methyl p-nitrobenzenesulfonate, which share with DEPC reactivity against histidine residues, also led to inhibition of alanine transport through systems A and ASC. The presence of Na+ (100 mM NaCl) and L-alanine (10 mM) during exposure to vesicles to DEPC protected against inactivation of system A (but not system ASC) transport activity. This protective effect was specific and required the presence of L-alanine since the presence of L-phenylalanine alone (10 mM) or L-phenylalanine plus Na+ (100 mM NaCl) did not cause any detectable protection. This overall pattern of protection is opposite to that previously found against specific sulfhydryl reagents (i.e. N-ethylmaleimide), where protection of system ASC was nearly maximal. The pH profile for DEPC-dependent inhibition of system A transport activity suggests modification of amino acid residue(s) with a pKr of approximately 7, most likely histidine(s), in close parallel with the pH dependence of system A transport activity. Our results suggest the presence of critical histidine residues on the system A carrier that may be responsible for the pH dependence of system A transport activity.     

Evidence for allosteric regulation of pH-sensitive System A (SNAT2) and System N (SNAT5) amino acid transporter activity involving a conserved histidine residue

System A and N amino acid transporters are key effectors of movement of amino acids across the plasma membrane of mammalian cells. These Na+-dependent transporters of the SLC38 gene family are highly sensitive to changes in pH within the physiological range, with transport markedly depressed at pH 7.0. We have investigated the possible role of histidine residues in the transporter proteins in determining this pH-sensitivity. The histidine-modifying agent DEPC (diethyl pyrocarbonate) markedly reduces the pH-sensitivity of SNAT2 and SNAT5 transporters (representative isoforms of System A and N respectively, overexpressed in Xenopus oocytes) in a concentration-dependent manner but does not completely inactivate transport activity. These effects of DEPC were reversed by hydroxylamine and partially blocked in the presence of excess amino acid substrate. DEPC treatment also blocked a reduction in apparent affinity for Na+ (K0.5Na+) of the SNAT2 transporter at low external pH. Mutation of the highly conserved C-terminal histidine residue to alanine in either SNAT2 (H504A) or SNAT5 (H471A) produced a transport phenotype exhibiting reduced, DEPC-resistant pH-sensitivity with no change in K0.5Na+ at low external pH. We suggest that the pH-sensitivity of these structurally related transporters results at least partly from a common allosteric mechanism influencing Na+ binding, which involves an H+-modifier site associated with C-terminal histidine residues.     

Non-competitive inhibition of myo-inositol transport in cultured bovine retinal capillary pericytes by glucose and reversal by Sorbinil

myo-Inositol transport by retinal capillary pericytes in culture was characterized. The major myo-inositol transport process was sodium-dependent, ouabain-sensitive, and saturable at 40 mM, indicating a carrier-mediated process. The sodium ion concentration required to produce one-half the maximal rate of myo-inositol uptake ([Na+]0.5) did not show dependence on the external myo-inositol concentration (22.3 mM sodium for 0.005 mM myo-inositol; 18.2 mM sodium for 0.05 mM myo-inositol). myo-Inositol transport was an energy-dependent, active process functioning against a myo-inositol concentration gradient. The kinetics of the sodium-dependent system fitted a 'velocity type' co-transport model where binding of sodium ion to the carrier increased the velocity (Vmax 28 to 313 pmol myo-inositol/micrograms DNA per 20 min when [Na+] varied from 9 to 150 mM) but not the affinity for myo-inositol (Km 0.92 to 0.83 mM when [Na+] varied from 9 to 150 mM). Metabolizable hexoses (D-glucose or D-galactose; greater than 5 mM) inhibited myo-inositol uptake. Dixon-plot analysis indicated that the inhibition was non-competitive with a Ki of 22.7 mM for D-glucose and 72.6 mM for D-galactose. The inhibition was significantly reversed by Sorbinil (0.1 mM), an aldose reductase inhibitor. In contrast, high concentrations of non-metabolizable hexoses (L-glucose, 3-O-methyl-D-glucose), or partially metabolizable 2-deoxy-D-glucose, did not significantly inhibit myo-inositol uptake. The inhibitory effect of D-glucose or D-galactose on myo-inositol transport appeared to be related to glucose or galactose metabolism via the polyol pathway.     

Characterization of essential arginine residues implicated in the renal transport of phosphate and glucose.

We have characterized the reaction of arginine-specific reagents with the phosphate and glucose carriers of the kidney brush-border membrane. The inhibition of phosphate and glucose transport by phenylglyoxal follows pseudo-first-order kinetics. The rate of inactivation of phosphate transport by 50 mM phenylglyoxal was about 3-fold higher than that for glucose transport (kapp was 0.052 s-1 for the uptake of phosphate and 0.019 s-1 for the uptake of glucose). The order of the reaction, n, with respect to phenylglyoxal was 1.25 and 1.31 for the inactivation of phosphate and glucose transport, respectively. The inactivation of phosphate flux by p-hydroxyphenylglyoxal also follows pseudo-first-order kinetics, but the inhibition rate (kapp = 0.0012 s-1) was slower than with phenylglyoxal. The inactivation increased with the alkalinity of the preincubation medium for both phosphate and glucose fluxes and was maximal at pH 9.0. The inactivation of phosphate flux by phenylglyoxal depends upon the presence of an alkaline intravesicular pH. Extravesicular pH does not affect the reaction. Phenylglyoxal does not interfere with the recycling of the protonated carrier since phosphate uptake is inhibited independently of the pH used for transport measurements. Moreover, phenylglyoxal completely abolished trans stimulation by phosphate. Trans sodium inhibited phosphate uptake and abolished the pH profile of phosphate uptake.     

In vitro effect of ethanol on sodium and glucose transport in rabbit renal brush border membrane vesicles.

The effect of ethanol on sodium and glucose transport in rabbit renal brush border membrane vesicles was examined. When membrane vesicles were preincubated in the presence of ethanol the sodium-dependent D-glucose uptake was significantly inhibited. This effect, as suggested by O'Neill et al. (1986) FEBS Lett. 194, 183-188, may be due to a faster collapse of the Na+ gradient. As a matter of fact, the amiloride-insensitive sodium pathway was increased by ethanol in our brush border membrane preparation. However, sodium/D-glucose cotransport was inhibited by ethanol, although to a lesser degree, also in the absence of a sodium gradient. In addition, ethanol inhibited glucose-dependent sodium uptake, suggesting that a direct interaction with the translocator was involved. This conclusion was also supported by kinetic measurements showing a decrease of Vmax and an increase in Km for glucose in membrane vesicles treated with ethanol. Moreover, ethanol influenced the interaction of phlorizin with the cotransporter: uptake experiments performed in the presence of the two inhibitors demonstrated that phlorizin and ethanol behave as not mutually exclusive inhibitors of D-glucose transport. These data indicate that in rabbit renal brush border membranes ethanol not only affects the 'passive pathway', i.e. the sodium permeability, but it also directly interferes with carrier functions.     

Sodium-dependent D-glucose transport in brush-border membrane vesicles from isolated rat small intestinal villus and crypt epithelial cells

Differentiation and maturation of enterocytes occur with migration from the crypt to villus compartments. To investigate the effect of epithelial cell differentiation on sodium-dependent D-glucose transport, brush-border membrane vesicles were prepared from small intestinal epithelial cell suspensions selectively isolated from villus and crypt populations. Enterocytes were isolated with a morphologically monitored sequential cell dissociation method. Thymidine kinase, sucrase, and alkaline phosphatase activities were measured as differentiation markers of specific cell populations. Brush-border membrane vesicles were purified and their kinetic characteristics defined with a rapid filtration method under conditions of a zero-trans, 100 mM cis-NaSCN gradient. Typical "overshoot" phenomena characteristic of sodium D-glucose cotransport were observed for both villus (five- to eight-fold equilibrium values) and crypt brush-border membrane vesicles (two- to four-fold equilibrium values). Kinetics analyses of the initial D-glucose flux in brush-border membrane vesicles suggested the presence of at least two sodium-dependent D-glucose carriers in the villus and only a single carrier in the crypt compartments. These data indicate that sodium D-glucose cotransport occurs in brush-border membranes of both villus and crypt populations. Moreover, quantitative and qualitative differences between these two membrane populations suggest that epithelial D-glucose transport processes are differentiation dependent and reflect the degree of enterocyte development.     

Phosphate transport by rat intestinal basolateral-membrane vesicles.

The characteristics of phosphate transport across intestinal basolateral membranes of the rat were determined by using enriched preparations in which uphill Na+-dependent D-glucose transport could not be demonstrated, but ATP-dependent Ca2+ transport was present. Phosphate transport was saturable, Na+-dependent and exhibited Michaelis-Menten kinetics. Vmax. was 51.1 +/- 4.2 pmol/10 s per mg of protein and Km was 14 +/- 3.9 microM. The transport process was electroneutral. Tracer-exchange experiments and counter-transport studies confirmed the presence of a Na+-Pi carrier at the basolateral membrane. The presence of inside-positive membrane potential did not enhance phosphate uptake, indicating that the Na+ effect is secondary to the presence of the Na+-Pi carrier rather than an induction of positive membrane potential. The stoichiometry of this carrier at pH 7.4 was 2 Na+:1 phosphate, as shown by direct studies utilizing the static-head method. These studies are the first to determine the presence of a phosphate carrier at the basolateral membrane.     

Effect of parathyrin on the transport properties of isolated renal brush-border vesicles.

The transport properties of brush-border membrane vesicles isolated by a calcium-precipitation method from the renal cortex of normal and parathyrin (parathyroid hormone)-treated rats were studied by a rapid-filtration technique. Parathyrin elicited a dose-dependent decrease in the Na+-dependent phosphate uptake by the brush-border membrane vesicles, but the uptake of D-glucose, Na+ and mannitol was not affected. A maximum inhibition of 30% was observed after the application of 30 U.S.P. units intramuscularly 1 h before the animals were killed. Intravenous infusion of dibutyryl cyclic AMP (0.5-1.5 MG) also decreased the phosphate uptake by the brush-border vesicles. Both dibutyryl cyclic AMP and parathyrin were ineffective when added in vitro to brush-border membrane vesicles isolated from normal rats. These data suggest that parathyrin exerts its action on the phosphate reabsorption in the renal proximal tubule by affecting the Na+/phosphate co-transport system in the brush-border membrane. The effects of parathyrin on Na+ and glucose transport, however, seem to be due to alterations to the driving forces for transport and not to the brush-border transport systems.     

Glutamine transport in C6 glioma cells

Glutamine transport across the cell membranes of a variety of mammalian tissues is mediated by at least four transport systems: a sodium-independent system L, and sodium-dependent systems A, ASC and N, the latter occurring in different tissue-specific variants. In this study we assessed the contribution of these systems to the uptake of [(3)H]glutamine in C6 rat glioma cells. The sodium-dependent uptake, which accounted for more than 80% of the total uptake, was not inhibited by 2-methylaminoisobutyric acid (MeAIB), indicating that system A was inactive, possibly being depressed by glutamine present in the culture medium. About 80% of the sodium-dependent uptake was mediated by system ASC, which differed from system ASC common to other CNS- and non-CNS tissues by its pH-dependence and partial lithium tolerance. The residual 20% of sodium-dependent uptake appeared to be mediated by system N, which was identified as a component resistant to inhibition by MeAIB+threonine. The system N in C6 cells appeared to be neither fully compatible with the neuronal system Nb, nor with the N system described in astrocytes: it differed from the former in being strongly inhibited by histidine and showing fair tolerance for lithium, and from the latter in its pH-insensitivity and strong inhibition by glutamate. The sodium-independent glutamine uptake differed from the astrocytic or neuronal uptake in its relatively weak inhibition by system L substrates and a strong inhibition by system ASC substrates, indicating a possible contribution of a variant of the ASC system.     

Glucose and insulin co-regulate the glucose transport system in primary cultured adipocytes. A new mechanism of insulin resistance

We have previously shown in primary cultured rat adipocytes that insulin acts at receptor and multiple postreceptor sites to decrease insulin's subsequent ability to stimulate glucose transport. To examine whether D-glucose can regulate glucose transport activity and whether it has a role in insulin-induced insulin resistance, we cultured cells for 24 h in the absence and presence of various glucose and insulin concentrations. After washing cells and allowing the glucose transport system to deactivate, we measured basal and maximally insulin-stimulated 2-deoxyglucose uptake rates (37 degrees C) and cell surface insulin binding (16 degrees C). Alone, incubation with D-glucose had no effect on basal or maximal glucose transport activity, and incubation with insulin, in the absence of glucose, decreased maximal (but not basal) glucose transport rates only 18% at the highest preincubation concentration (50 ng/ml). However, in combination, D-glucose (1-20 mM) markedly enhanced the long-term ability of insulin (1-50 ng/ml) to decrease glucose transport rates in a dose-responsive manner. For example, at 50 ng/ml preincubation insulin concentration, the maximal glucose transport rate fell from 18 to 63%, and the basal uptake rate fell by 89%, as the preincubation D-glucose level was increased from 0 to 20 mM. Moreover, D-glucose more effectively promoted decreases in basal glucose uptake (Ki = 2.2 +/- 0.4 mM) compared with maximal transport rates (Ki = 4.1 +/- 0.4 mM) at all preincubation insulin concentrations (1-50 ng/ml). Similar results were obtained when initial rates of 3-O-methylglucose uptake were used to measure glucose transport. D-glucose, in contrast, did not influence insulin-induced receptor loss. In other studies, D-mannose and D-glucosamine could substitute for D-glucose to promote the insulin-induced changes in glucose transport, but other substrates such as L-glucose, L-arabinase, D-fructose, pyruvate, and maltose were without effect. Also, non-metabolized substrates which competitively inhibit D-glucose uptake (3-O-methylglucose, cytochalasin B) blocked the D-glucose plus insulin effect.(ABSTRACT TRUNCATED AT 400 WORDS)     

Sodium-dependent nucleoside transport in mouse intestinal epithelial cells. Two transport systems with differing substrate specificities

Nucleoside transport was examined in freshly isolated mouse intestinal epithelial cells. The uptake of formycin B, the C nucleoside analog of inosine, was concentrative and required extracellular sodium. The initial rate of sodium-dependent formycin B transport was saturable with a Km of 45 +/- 3 microM. The purine nucleosides adenosine, inosine, guanosine, and deoxyadenosine were all good inhibitors of sodium-dependent formycin B transport with 50% inhibition (IC50) observed at concentrations less than 30 microM. Of the pyrimidine nucleosides examined, only uridine (IC50, 41 +/- 9 microM) was a good inhibitor. Thymidine and cytidine were poor inhibitors with IC50 values greater than 300 microM. Direct measurements of [3H]thymidine transport revealed, however, that the uptake of this nucleoside was also mediated by a sodium-dependent mechanism. Thymidine transport was inhibited by low concentrations of cytidine, uridine, adenosine, and deoxyadenosine (IC50 values less than 25 microM), but not by formycin B, inosine, or guanosine (IC50 values greater than 600 microM). These data indicate that there are two sodium-dependent mechanisms for nucleoside transport in mouse intestinal epithelial cells, and that formycin B and thymidine may serve as model substrates to distinguish between these transporters. Neither of these sodium-dependent transport mechanisms was inhibited by nitrobenzylmercaptopurine riboside (10 microM), a potent inhibitor of one of the equilibrative (facilitated diffusion) nucleoside transporters found in many cells.     

Ubiquitin-Directed Antibodies Inhibit Neuronal Transporters in Rat Brain Synaptosomes

Affinity-purified antibodies specific for ubiquitin were found to inhibit the sodium-dependent uptake of [3H]choline, gamma-[3H]aminobutyric acid [( 3H]GABA), [3H]glutamate, [3H]norepinephrine, [3H]aspartate, and [3H]serotonin in rat cerebral cortical synaptosomes at a low concentration (10 micrograms/ml). These antibodies (termed anti-Ub) had no effect on the sodium-independent uptake of these substances or their calcium-dependent efflux. Synaptosomal [3H]deoxyglucose uptake was not affected in normal Krebs Ringer buffer containing 10 mM glucose, but was inhibited in glucose-free medium. Other nonneuronal sodium-dependent transport processes were found to be unaffected by 10 micrograms/ml anti-Ub, suggesting that anti-Ub does not bind indiscriminantly to sodium-binding sites on sodium-dependent organic solute transporters. Finally, anti-Ub inhibited sodium-dependent [3H]GABA and [3H]glutamate uptake in plasma membrane ghosts, devoid of membrane potential, which were derived from rat cerebral cortical synaptosomes. These results suggest that neuronal transporters or sites proximal to them may be ubiquitinylated on the plasma membrane surface.