Expression of rat liver Na+/L-alanine co-transport in Xenopus laevis oocytes. Effect of glucagon in vivo.

Poly(A)+ RNA (mRNA) isolated from rat liver was injected into Xenopus laevis oocytes, and expression of Na+/L-alanine transport was assayed by measuring Na(+)-dependent uptake of L-[3H]alanine. Expression of Na+/L-alanine transport was detected 3-7 days after mRNA injection, and was due to an increment of the Na(+)-dependent component. After injection of 40 ng of total mRNA, Na(+)-dependent uptake of L-alanine was 2.5-fold higher than in water-injected oocytes. In contrast with Na+/L-alanine transport by water-injected oocytes, expressed Na+/L-alanine transport was inhibited by N-methylaminoisobutyric acid, was inhibited by an extracellular pH of 6.5 and was saturated at approx. 1 mM-L-alanine. After sucrose-density-gradient fractionation, highest expression of Na+/L-alanine uptake was observed with mRNA of 1.9-2.5 kb in length. Compared with mRNA isolated from control rats, mRNA isolated from glucagon-treated rats showed a approx. 2-fold higher expression of Na+/L-alanine transport. The results demonstrate that both liver Na+/L-alanine transport systems (A and ASC) can be expressed in X. laevis oocytes. Furthermore, the data obtained with mRNA isolated from glucagon-treated rats suggest that glucagon regulates liver Na+/L-alanine transport (at least in part) via the availability of the corresponding mRNA.     

Expression of Madin-Darby canine kidney cell Na(+)-and Cl(-)-dependent taurine transporter in Xenopus laevis oocytes.

Expression of a Madin-Darby canine kidney (MDCK) cell taurine transporter was examined in Xenopus oocytes that had been injected with poly(A)+ RNA extracted from MDCK cells. Compared with water-injected oocytes, injection of total poly(A)+ RNA resulted in an increase in Na(+)-dependent taurine uptake which was directly related to the amount of RNA injected. The magnitude of expression in poly(A)+ RNA-injected oocytes was 5-10-fold higher than that of water-injected oocytes. Since the Vmax of taurine uptake in MDCK cells is increased by culture in hypertonic medium, we compared oocyte taurine uptake after injection with poly(A)+ RNA from MDCK cells cultured in hypertonic medium with uptake in oocytes injected with poly(A)+ RNA from hypertonic cells elicited twice the taurine uptake elicited by poly(A)+ RNA from isotonic cells. The transporter expressed in oocytes was like that in MDCK cells: it was completely dependent on external sodium and was also anion dependent (Cl- greater than or equal to Br- greater than SCN- much greater than gluconate-). Other beta-amino acids, beta-alanine and hypotaurine, inhibited taurine uptake, but L-alanine and 2-(methylamino) isobutyric acid did not. The apparent Km of the transporter was 7.0 microM. After size fractionation on a sucrose density gradient, poly(A)+ RNA encoding for the MDCK taurine transporter was found in the fraction whose average size was 4.4 kilobases.     

Expression of rat renal sodium/phosphate cotransporter in Xenopus laevis oocytes.

In an attempt to identify the renal Na+/Pi cotransporter, Xenopus laevis oocytes were used to express mRNA isolated from the renal cortex of rat kidney. Na(+)-dependent uptake of Pi in oocytes, injected with mRNA, resulted in an increase of 2-4-fold as compared to oocytes injected with water. Both the new expressed and endogenous Na(+)-dependent Pi uptake activity were inhibited with 2 mM phosphonoformic acid (PFA). Expression of Pi uptake into oocytes was dose-dependent with the amount of mRNA injected. When mRNA was fractionated on a sucrose gradient, a mRNA fraction of 2.5 kilobases expressed the Na+/Pi cotransport activity in oocytes. This fraction resulted in a 6-fold stimulation of Na(+)-dependent Pi transport when compared to oocytes injected with water. The Km and Vmax for Na(+)-dependent Pi uptake were 0.18 mM and 118 pmol/oocyte per 30 min, respectively.     

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.     

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.     

Cloning of a Na(+)- and Cl(-)-dependent betaine transporter that is regulated by hypertonicity.

Many hypertonic bacteria, plants, marine animals, and the mammalian renal medulla are protected from the deleterious effects of high intracellular concentrations of electrolytes by accumulating high concentrations of the nonperturbing osmolyte betaine. When kidney-derived Madin-Darby canine kidney (MDCK) cells are cultured in hypertonic medium, they accumulate betaine to 1,000 times its medium concentration. This results from induction by hypertonicity of high rates of betaine transport into cells. We have isolated a cDNA (BGT-1) encoding a renal betaine transporter by screening an MDCK cell cDNA library for expression of a betaine transporter in Xenopus oocytes. The cDNA encodes a single protein of 614 amino acids, with an estimated molecular weight of 69 kDa. The deduced amino acid sequence exhibits highly significant sequence and topographic similarity to brain gamma-amino-n-butyric acid (GABA) and noradrenaline transporters, suggesting that the renal BGT-1 is a member of the brain GABA/noradrenaline transporter gene family. Expression in oocytes indicates that the BGT-1 protein has both betaine and GABA transport activities that are Cl(-)- as well as Na(+)-dependent and functionally similar to betaine and GABA transport in MDCK cells. Northern hybridization indicates that transporter mRNA is localized to the kidney medulla and is induced in MDCK cells by hypertonicity.     

Cloning of the cDNa for a Na+/myo-inositol cotransporter, a hypertonicity stress protein.

Kidney medullary cells in situ, as well as kidney-derived Madin-Darby canine kidney (MDCK) cells accumulate nonperturbing, small organic solutes (osmolytes), including myo-inositol, when bathed in hypertonic media. Accumulation of osmolytes balances the osmolality of extracellular fluid without raising intracellular salts that would perturb cellular functions. In hypertonic media, increased myo-inositol accumulation is the result of increased activity of a Na+/myo-inositol cotransporter. We have isolated a cDNA encoding a Na+/myo-inositol cotransporter from MDCK cells using expression in Xenopus oocytes. The cDNA sequence predicts a protein of 718 amino acids with a significant amino acid sequence similarity to the Na+/D-glucose cotransporters of absorbing epithelia. Transporter mRNA is present in kidney and brain and is markedly induced in MDCK cells by medium hypertonicity, demonstrating that adaptation to hypertonic stress involves up-regulation of transporter mRNA accumulation.     

Expression of Na(+) / D-glucose cotransport in Xenopus laevis oocytes by injection of poly(A)(+) RNA isolated from lobster (Homarus americanus) hepatopancreas

Xenopus laevis oocytes were used for expression and characterization of lobster (Homarus americanus) hepatopancreas Na(+)-dependent D-glucose transport activity. Poly(A)(+) RNA from the whole hepatopancreatic tissue was injected and transport activity was assayed by alpha-D-[2-(3)H] glucose. Injection of lobster hepatopancreatic poly(A)(+) RNA resulted in a dose (1-20 ng) and time (1-5 days) dependent increase of Na(+)-dependent D-glucose uptake. Kinetics of Na(+)-dependent glucose transport was a hyperbolic function (K(m)=0.47+/-0.04 mM) of external D-glucose concentration and a sigmoidal function (K(Na)=68.32+/-1.57 mM; Hill coefficient=2.22+/-0.09) of external Na(+) concentration. In addition, Na(+)-dependent D-glucose uptake was significantly inhibited by both (0.1-0.5 mM) phloridzin and (0.1-0.5 mM) methyl-alpha-D-glucopyranoside. After size fractionation through a sucrose density gradient, poly(A)(+) RNA fractions with an average length of 2-4 kb induced a twofold increase in Na(+)-dependent phloridzin-inhibited D-glucose uptake as compared to total poly(A)(+) RNA-induced uptake. The results of this study provide the functional basis to screen lobster hepatopancreatic cDNA libraries for clones encoding putative and still not known crustacean SGLT-type Na(+)/glucose co-transporter(s).     

Chinese hamster ovary mRNA-dependent, Na(+)-independent L-leucine transport in Xenopus laevis oocytes.

In freshly prepared uninjected folliculated oocytes, Na(+)-independent leucine uptake is mediated predominantly by a system L-like transport system. Removal of follicular cells, however, results in an irreversible loss of this transport activity. When total poly(A)+ mRNA derived from Chinese hamster ovary (CHO) cells was injected into prophase-arrested stage V or VI Xenopus laevis oocytes, enhanced expression of Na(+)-independent leucine transport was observed. The injected mRNAs associated with increased levels of leucine uptake were between 2 and 3 kb in length. The newly expressed leucine transport activity exhibited important differences from the known characteristics of system L, which is the dominant Na(+)-independent leucine transporter in CHO cells as well as in freshly isolated folliculated oocytes. The CHO mRNA-dependent leucine uptake in oocytes was highly sensitive to the cationic amino acids lysine, arginine, and and ornithine (> 95% inhibition). As with the leucine uptake, an enhanced lysine uptake was also observed in size-fractionated CHO mRNA-injected oocytes. The uptakes of leucine and lysine were mutually inhibitable, suggesting that the newly expressed transporter was responsible for uptakes of both leucine and lysine. The inhibition of uptake of lysine by leucine was Na+ independent, thus clearly distinguishing it from the previously reported endogenous system y+ activity. Furthermore, the high sensitivity to tryptophan of the CHO mRNA-dependent leucine transport was in sharp contrast to the properties of the recently cloned leucine transport-associated gene from rat kidney tissue, although leucine transport from both sources was sensitive to cationic amino acids. Our results suggest that there may be a family of leucine transporters operative in different tissues and possibly under different conditions.     

Cell surface expression and bile acid transport function of one topological form of m-epoxide hydrolase

The bifunctional hepatic protein, microsomal epoxide hydrolase (mEH), plays a central role in the metabolism of many xenobiotics as well as mediating the Na(+)-dependent uptake of bile acids in parallel with the Na(+)-taurocholate co-transporting protein (ntcp). Previous studies have established that mEH is expressed in the endoplasmic reticulum with two topological orientations, where the type II form is targeted to the plasma membrane. In this report the topology and transport properties of mEH as a function of plasma membrane expression in cultured hepatocytes, transfected Madin-Darby canine kidney cells expressing mEH (MDCK[mEH]), and the human hepatoma cell line, HepG2, were studied using confocal fluorescence microscopy and substrate uptake measurements. Analysis of mEH localization with an anti-mEH monoclonal antibody demonstrated the expression of one topological form on the plasma membrane of hepatocytes and MDCK[mEH] cells where both systems exhibited Na(+)-dependent bile acid uptake. In contrast, Na(+)-dependent bile acid transport in HepG2 cells and hepatocytes in culture (72 h) was substantially reduced as was the expression of ntcp. Although the total mEH level was undiminished, the decrease of bile acid transport was associated with the loss of mEH surface expression possibly resulting from an alteration in mEH endoplasmic reticulum topology and/or the plasma membrane protein targeting system in these de-differentiated cells.     

Expression of mammalian renal transporters in Xenopus laevis oocytes

We have injected mRNA from rabbit renal cortex into Xenopus oocytes and demonstrated the expression of renal carriers for Na(+)-independent transport of L-phenylalanine and L-lysine and Na(+)-dependent transport of L-alanine and succinate. Maximal expression of renal amino acid transporters occurred 6-8 days following mRNA injection. The proteins responsible for transport of these four substrates were translated from mRNAs which are between 1.5 and 3.0 kb. This information serves as a starting point for expression cloning of these transport proteins.     

Expression of the mammalian system A neutral amino acid transporter in Xenopus oocytes

In this report, we demonstrate the expression of the mammalian System A neutral amino acid transporter in Xenopus laevis oocytes following microinjection of mRNA from rat liver, Chinese hamster ovary (CHO) cells, and human placenta. Stage 6 oocytes were injected with poly(A+) mRNA from one of these three sources and incubated for 24 h prior to assaying Na(+)-dependent 2-aminoisobutyric acid transport to monitor the increase in System A activity. The endogenous 2-aminoisobutyric acid uptake rates in oocytes were sufficiently slow so as to provide a low background value that was subtracted to obtain transport rates for the mammalian carrier alone. The degree of expression of the mammalian System A activity in Xenopus oocytes corresponded to the known transport rates in the tissue from which the mRNA was prepared. For example, hepatic mRNA from glucagon-treated rats produced greater System A activity than mRNA from control animals, and the mRNA from the CHO transport mutant cell line alar4-H3.9, which overproduces System A, resulted in higher transport rates than mRNA from the parental cell line (CHO-K1). Fractionation of total mRNA poly(A+) by nondenaturing agarose gel electrophoresis revealed transport activity associated with a 2.0-2.5-kilobase mRNA fraction common to each of the three tissues tested.     

mRNA-induced expression of the cardiac Na+-Ca2+ exchanger in Xenopus oocytes

Xenopus oocytes were injected with total mRNA isolated from hearts of 1-day-old chicks. After 5 days of incubation the follicular cell layers were removed and the oocytes were loaded with Na+ by incubation in hypertonic EGTA solution at 37 degrees C. The Na+-loaded oocytes accumulated 45Ca2+ from a Na+-free medium at a 3-18-fold higher rate than noninjected oocytes or oocytes injected with control solution containing no mRNA. Oocytes not subjected to the Na+-loading procedure showed no mRNA-dependent 45Ca2+ uptake. Size fractionation of the mRNA using sucrose density gradient centrifugation under denaturing conditions led to the identification of a 25 S fraction competent for induction of the Na+-Ca2+ exchange system.     

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.     

Characterization of a Na(+)-K(+)-2Cl- cotransport system in oocytes from Xenopus laevis

In order to characterize the transport systems mediating K+ uptake into oocytes, flux studies employing 86Rb were performed on Xenopus oocytes stripped of follicular cells by pretreatment with Ca2(+)-Mg2(+)-free Barth's medium. Total Rb+ uptake consisted of an ouabain-sensitive and an ouabain-insensitive flux. In the presence of 100 mmol/l NaCl and 0.1 mmol/l ouabain the ouabain-insensitive flux amounted to 754.7 +/- 59.9 pmol/oocyte per h (n = 30 cells, i.e., 10 cells each from three different animals). In the absence of Na+ (Na+ substituted by N-methylglucamine) or when Cl- was replaced by NO3- the ouabain-insensitive flux was reduced to 84.4 +/- 42.9 and 79.2 +/- 12.1 pmol/oocyte per h, respectively (n = 50 cells). Furthermore, this Na(+)- and Cl(-)-dependent flux was completely inhibited by 10(-4) mol/l bumetanide, a specific inhibitor of the Na(+)-K(+)-2Cl- cotransport system. These results suggest that K+ uptake via a bumetanide-sensitive Na(+)-K(+)-2Cl- cotransport system represents a major K+ pathway in oocytes.     

Expression and characterization of the intestinal Na+/glucose cotransporter in COS-7 cells

Cells derived from the simian kidney, COS-7 cells, were transfected with a eucaryotic expression vector (pEUK-C1) containing the clone for the rabbit intestinal Na+/glucose cotransporter. Expression was monitored after transfection with lipofectin by measuring the initial rate of alpha-methylglucopyranoside (MeGlc) uptake. Cells transfected with vector containing the cDNA for the Na+/glucose cotransporter expressed Na(+)-dependent MeGlc transport. Neither control cells nor cells transfected with vector lacking cloned cDNA expressed the cotransporter. Na(+)-dependent MeGlc uptake into transfected cells was saturable (Km 150 microM), phlorizin-sensitive (Ki 11 microM), and inhibited by sugar analogs (D-glucose greater than MeGlc greater than D-galactose greater than 3-O-methyl-D-glucoside greater than D-allose much greater than L-glucose). Europium was able to mimic Na+ in driving MeGIC uptake. Finally, tunicamycin, an inhibitor of asparagine-linked glycosylation, inhibited the expression of Na(+)-dependent MeGlc transport 80%. We conclude that the rabbit intestinal Na+/glucose cotransporter expressed in COS-7 cell exhibits very similar kinetic properties to that in the native brush border and to that expressed in Xenopus oocytes. In addition, N-linked glycosylation appears to be important for functional expression of this membrane protein.     

Expression of the mouse macrophage cystine transporter in Xenopus laevis oocytes.

System xc- mediates transport of cystine and glutamate across the mammalian plasma membrane in a Na(+)-independent manner. This transport activity can be induced in mouse peritoneal macrophages during culture by diethylmaleate, a sulfhydryl-reactive agent. We injected mRNA from such macrophages into Xenopus oocytes and demonstrated the expression of System xc-, i.e., a Na(+)-independent, glutamate-inhibitable cysteine transport system. The expressed cystine transport activity depended on the assay temperature, in that cystine uptake measured at 37 degrees C was severalfold higher than that measured at 20 degrees C. Injection of size-fractionated mRNA indicated that the System xc- transporter of the mouse macrophage is encoded by mRNA of 1.5 to 2.9 kb.     

GSH Transport in Immortalized Mouse Brain Endothelial Cells

We have previously shown GSH transport across the blood-brain barrier in vivo and expression of transport in Xenopus laevis oocytes injected with bovine brain capillary mRNA. In the present study, we have used MBEC-4, an immortalized mouse brain endothelial cell line, to establish the presence of Na+-dependent and Na+-independent GSH transport and have localized the Na+-dependent transporter using domain-enriched plasma membrane vesicles. In cells depleted of GSH with buthionine sulfoximine, a significant increase of intracellular GSH could be demonstrated only in the presence of Na+. Partial but significant Na+ dependency of [35S]GSH uptake was observed for two GSH concentrations in MBEC-4 cells in which gamma-glutamyltranspeptidase and gamma-glutamylcysteine synthetase were inhibited to ensure absence of breakdown and resynthesis of GSH. Uniqueness of Na+-dependent uptake in MBEC-4 cells was confirmed with parallel uptake studies with Cos-7 cells that did not show this activity. Molecular form of uptake was verified as predominantly GSH, and very little conversion of [35S]cysteine to GSH occurred under the same incubation conditions. Poly(A)+ RNA from MBEC expressed GSH uptake with significant (approximately 40-70%) Na+ dependency, whereas uptake expressed by poly(A)+ RNA from HepG2 and Cos-1 cells was Na+ independent. Plasma membrane vesicles from MBEC were separated into three fractions (30, 34, and 38% sucrose, by wt) by density gradient centrifugation. Na+-dependent glucose transport, reported to be localized to the abluminal membrane, was found to be associated with the 38% fraction (abluminal). Na+-dependent GSH transport was present in the 30% fraction, which was identified as the apical (luminal) membrane by localization of P-glycoprotein 170 by western blot analysis. Localization of Na+-dependent GSH transport to the luminal membrane and its ability to drive up intracellular GSH may find application in the delivery of supplemented GSH to the brain in vivo.