Isolation and characterization of an L1210 cell line retaining the sodium-dependent carrier cif as its sole nucleoside transport activity

Nucleoside permeation across mammalian cell membranes is complex with at least four distinct transporters known. Two of these (es and ei) are equilibrative (facilitated diffusion) carriers that have been studied is considerable detail. The other two (cif and cit) are concentrative, Na(+)-dependent carriers. A major obstacle to the characterization of the latter two mechanisms has been the lack of suitable model systems expressing only a single nucleoside transport activity. The present study describes the isolation of a cell line that has cif as its sole nucleoside transporter. L1210/MC5-1 cells, which have es and cif transport activity, were mutagenized and plated in soft agar containing two cytotoxic nucleosides (tubercidin (7-deazaadenosine) and cytosine arabinoside) that are substrates for es but not cif. A clonal line (L1210/MA-27.1) was isolated which retained the capacity for Na(+)-dependent [3H]formycin B transport but was unable to transport [3H]thymidine, a substrate for es but not cif. Failure of the mutant to transport thymidine was also demonstrated by the inability of thymidine (with adenine as a purine source) to rescue these cells from methotrexate toxicity. Furthermore, the mutant lacked nitrobenzylthioinosine (NBMPR) binding activity (an integral part of the es transporter) as demonstrated by reversible NBMPR binding and photoaffinity labeling with [3H]NBMPR. Loss of es transport activity was also demonstrated by the failure of NBMPR to affect the toxicity of 2-chlorodeoxyadenosine (IC50 approximately 30 nM) in L1210/MA27.1 cells. In contrast, NBMPR decreased the IC50 for 2-chlorodeoxyadenosine from 100 to 30 nM in the parental L1210/MC5-1 cell line. These results are consistent with the mechanism of NBMPR potentiation of 2-chlorodeoxyadenosine toxicity in L1210 cells being a blockade of efflux via es while the nucleoside is pumped into the cells by the concentrative cif carrier.     

Isolation and characterization of a mutant of L1210 murine leukemia deficient in nitrobenzylthioinosine-insensitive nucleoside transport

L1210 mouse leukemia cells exhibit two distinct types of nucleoside transport activity that have similar kinetic properties and substrate specificity, but differ markedly in their sensitivity to the inhibitor nitrobenzylthioinosine (NBMPR) (Belt, J. A. (1983) Mol. Pharmacol. 24, 479-484). It is not known whether these two transport activities are mediated by a single protein or by separate and distinct nucleoside transport proteins. We have isolated a mutant from the L1210 cell line that has lost the NBMPR-insensitive component of nucleoside transport, but retains NBMPR-sensitive transport. In the parental cell line 20-40% of the nucleoside transport activity is insensitive to 1 microM NBMPR. In the mutant, however, uridine and thymidine transport are almost completely inhibited by NBMPR. Consistent with the loss of NBMPR-insensitive transport, the mutant cells can be protected from the toxic effects of several nucleoside analogs by NBMPR. In contrast, the toxicity of the same analogs in the wild type cells is not significantly affected by NBMPR, presumably due to uptake of the nucleosides via the NBMPR-insensitive transporter. On the other hand, NBMPR-sensitive transport in the mutant appears to be unaltered. The mutant is not resistant to cytotoxic nucleosides in the absence of NBMPR and the cells retain the wild type complement of high affinity binding sites for NBMPR. Furthermore, the affinity of the binding site for the inhibitor is similar to that of parental L1210 cells. These results suggest that NBMPR-sensitive and NBMPR-insensitive nucleoside transport in L1210 cells are mediated by genetically distinct proteins. To our knowledge this is the first report of a mutant deficient in NBMPR-insensitive nucleoside transport.     

Characterization of nucleoside transport systems in cultured rat epididymal epithelium

The nucleoside transport systems in cultured epididymal epithelium were characterized and found to be similar between the proximal (caput and corpus) and distal (cauda) regions of the epididymis. Functional studies revealed that 70% of the total nucleoside uptake was Na(+) dependent, while 30% was Na(+) independent. The Na(+)-independent nucleoside transport was mediated by both the equilibrative nitrobenzylthioinosine (NBMPR)-sensitive system (40%) and the NBMPR-insensitive system (60%), which was supported by a biphasic dose response to NBMPR inhibition. The Na(+)-dependent [(3)H]uridine uptake was selectively inhibited 80% by purine nucleosides, indicating that the purine nucleoside-selective N1 system is predominant. Since Na(+)-dependent [(3)H]guanosine uptake was inhibited by thymidine by 20% and Na(+)-dependent [(3)H]thymidine uptake was broadly inhibited by purine and pyrimidine nucleosides, this suggested the presence of the broadly selective N3 system accounting for 20% of Na(+)-dependent nucleoside uptake. Results of RT-PCR confirmed the presence of mRNA for equilibrative nucleoside transporter (ENT) 1, ENT2, and concentrative nucleoside transporter (CNT) 2 and the absence of CNT1. It is suggested that the nucleoside transporters in epididymis may be important for sperm maturation by regulating the extracellular concentration of adenosine in epididymal plasma.     

Na(+)-dependent, active and Na(+)-independent, facilitated transport of formycin B in mouse spleen lymphocytes

Na(+)-dependent, active and Na(+)-independent facilitated nucleoside transport were characterized in mouse spleen cells using rapid kinetic techniques and formycin B, a metabolically inert analog of inosine, as substrate. The Michaelis-Menten constants for formycin B transport by the two transporters were about 30 and 400 microM, respectively. The first-order rate constant for Na(+)-dependent transport was about 4-times higher than that for facilitated formycin B transport. The Na(+)-dependent carrier is specific for uridine and purine nucleosides and accumulates formycin B concentratively in an unmodified form. Concentrative accumulation was inhibited by ATP depletion and gramicidin and ouabain treatment of the cells. Our data indicate a single Na(+)-binding site on the Na(+)-dependent nucleoside carrier and a Michaelis-Menten constant for Na+ of about 10 mM. This transporter was not significantly inhibited by dipyridamole and nitrobenzylthioinosine, inhibitors of the facilitated transporter. The Na(+)-independent, facilitated nucleoside transporter of spleen cells exhibits properties comparable to those of the carriers present in mammalian cells in general. The B lymphocytes remaining after depletion of spleen cell populations of T lymphocytes by incubation with a combination of T-cell specific monoclonal antibodies plus complement exhibited about the same activities of active and facilitated nucleoside transport as the original suspension.     

L1210/B23.1 cells express equilibrative, inhibitor-sensitive nucleoside transport activity and lack two parental nucleoside transport activities.

Cultured mouse leukemia L1210 cells express the nucleoside-specific membrane transport processes designated es, ei, and cif. The es and ei processes are equilibrative, but may be distinguished by the high sensitivity of the former to 6-[(4-nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine (NBMPR); the cif process is mediated by a Na+/nucleoside cotransporter of low sensitivity to NBMPR. Cells of an ei-deficient clonal line, L1210/MC5-1, were mutagenized, and clones were selected in soft agar medium that contained (i) NBMPR (an inhibitor of es processes), (ii) erythro-9-(2-hydorxy-3-nonyl)adenine (an inhibitor of adenosine deaminase), and (iii) arabinofuranosyladenine (a cytotoxic substrate for the three nucleotide transporters). The selection medium did not allow es activity and selected against cells that expressed the Na(+)-linked cif process. Cells of the L1210/B23.1 clonal isolate were deficient in cif transport activity, and inward fluxes of formycin B, a poorly metabolized analog of inosine, were virtually abolished by NBMPR in these cells. In the mutant cells, nonisotopic formycin B behaved as a countertransport substrate during influx of [3H]formycin B, and inward fluxes of the latter were competitively inhibited by purine and pyrimidine nucleosides. The transport behavior of L1210/B23.1 cells indicates that (i) the mutation/selection procedure impaired or deleted the Na(+)-linked cif process and (ii) es nucleoside transport activity is expressed in the mutant cells.     

Na(+)-dependent, active nucleoside transport in S49 mouse lymphoma cells and loss in AE-1 mutant deficient in facilitated nucleoside transport

S49 murine lymphoma cells were examined for expression of various nucleoside transport systems using a non-metabolized nucleoside, formycin B, as substrate. Nitrobenzylthioinosine (NBTI)-sensitive, facilitated transport was the primary nucleoside transport system of the cells. The cells also expressed very low levels of NBTI-resistant, facilitated nucleoside transport as well as of Na(+)-dependent, concentrative formycin B transport. Concentrative transport was specific for uridine and purine nucleosides, just as the concentrative nucleoside transporters of other mouse and rat cells. A nucleoside transport mutant of S49 cells, AE-1, lacked both the NBTI-sensitive, facilitated and Na(+)-dependent, concentrative formycin B transport activity, but Na(+)-dependent, concentrative transport of alpha-aminoisobutyrate was not affected.     

Characterization of Na(+)-dependent, active nucleoside transport in rat and mouse peritoneal macrophages, a mouse macrophage cell line and normal rat kidney cells

Peritoneal rat macrophages expressed solely an Na(+)-dependent, concentrative nucleoside transporter, which possesses a single Na(+)-binding site and transports purine nucleosides and uridine but not thymidine or deoxycytidine. The Michaelis-Menten constants for formycin B and Na+ were about 6 microns and 14 mM, respectively, and the estimated Na+:formycin B stoichiometry was 1:1. Rat macrophages accumulated 5 microM formycin B to a steady-state level exceeding that in the medium by about 500-fold during 60 min of incubation at 37 degrees C. Concentrative formycin B transport was resistant to inhibition by nitrobenzylthioinosine, lidoflazine, dilazep and nifedipine, but was slightly inhibited by high concentrations of dipyridamole (greater than 10 microM) and probenecid (greater than 100 microM). Mouse peritoneal macrophages and lines of mouse macrophages and normal rat kidney cells expressed Na(+)-dependent, active nucleoside transport but in addition significant Na(+)-independent, facilitated nucleoside transport. Facilitated nucleoside transport in these cells was sensitive to inhibition by nitrobenzylthioinosine, dilazep and dipyridamole. The presence of these inhibitors greatly enhanced the concentrative accumulation of formycin B by these cells by inhibiting the efflux via the facilitated transporter of the formycin B actively transported into the cells. Whereas rat macrophages lacked high-affinity nitrobenzylthioinosine-binding sites, mouse macrophages and normal rat kidney cells possessed about 10,000 such sites/cell. Rat and mouse erythrocytes, rat lymphocytes, and lines of Novikoff rat hepatoma cells, Chinese hamster ovary cells, Mus dunni cells and embryonic monkey kidney cells expressed only facilitated nucleoside transport.     

Sodium-dependent nucleoside transport in mouse lymphocytes, human monocytes, and hamster macrophages and peritoneal exudate cells.

Mouse splenocytes and hamster peritoneal exudate cells (PEC), including macrophages, were shown to contain a predominantly Na(+)-dependent and inhibitor (6-[(4-nitrobenzyl)-mercapto]purine ribonucleoside, NBMPR)-resistant transport system for adenosine and other nucleosides. Adenosine (1 microM) was transported about equally in mouse thymocytes and human monocytes from peripheral blood by a Na(+)-dependent system and the NBMPR-sensitive facilitated diffusion system. Hamster PEC also transported inosine, tubercidin, formycin B, uridine, and thymidine in a NBMPR-insensitive manner. With the exception of formycin B, all nucleosides were phosphorylated intracellularly to varying degree, adenosine being almost fully phosphorylated. During the time course of routine experiments (30 s) formycin B was concentrated twofold over external medium levels (1 microM) without any drop-off in the transport rate. On the basis of metabolic studies it was estimated that uridine and tubercidin were also transported against a concentration gradient. Inosine, guanosine, 2'-deoxyadenosine, tubercidin, formycin B, and the pyrimidines uridine, thymidine, and cytidine (all 100 microM) inhibited transport of adenosine and inosine about 50-100%, while 3'-deoxyinosine showed weak inhibitory action. Transport of thymidine was strongly inhibited by nucleosides except by 3'-deoxyinosine. The Na(+)-dependent, active, and concentration transport system appears to be a feature of many immune-type cells, and its presence offers particular conceptual possibilities for the therapy of infections located in these cells.     

Dipyridamole-insensitive nucleoside transport in mutant murine T lymphoma cells

From a mutagenized population of S49 murine T lymphoma cells, a mutant cell line, JPA4, was selected that expressed an altered nucleoside transport capability. JPA4 cells transported low concentrations of purine nucleosides and uridine more rapidly than the parental S49 cell line. The transport of these nucleosides by mutant cells was insensitive to inhibition by either dipyridamole (DPA) or 4-nitrobenzylthioinosine (NBMPR), two potent inhibitors of nucleoside transport in mammalian cells. Kinetic analyses revealed that the apparent Km values for the transport of uridine, adenosine, and inosine were 3-4-fold lower in JPA4 cells compared to wild type cells. In contrast, the transport of both thymidine and cytidine by JPA4 cells was similar to that of parental cells, and transport of these pyrimidine nucleosides remained sensitive to inhibition by both NBMPR and DPA. Furthermore, thymidine was a 10-12-fold weaker inhibitor of inosine transport in JPA4 cells than in wild type cells. Thus, JPA4 cells appeared to express two types of nucleoside transport activities; a novel (mutant) type that was insensitive to inhibition by DPA and NBMPR and transported purine nucleosides and uridine, and a parental type that retained sensitivity to inhibitors and transported cytidine and thymidine. The phenotype of the JPA4 cell line suggests that the sensitivity of mammalian nucleoside transporters to both NBMPR and DPA can be genetically uncoupled from its ability to transport certain nucleoside substrates and that the determinants on the nucleoside transporter that interact with each nucleoside are not necessarily identical.     

Nitrobenzylthioinosine-insensitive uridine transport in human lymphoblastoid and murine leukemia cells

Both human lymphoblastoid (RPMI 6410) and murine leukemia (L1210) cells were found to have a component of uridine transport which is insensitive to the nucleoside transport inhibitor nitrobenzylthioinosine (NBMPR). In both cell lines NBMPR-insensitive uridine transport is inhibited by other nucleosides and by the sulfhydryl reagent p-chloromercuribenzenesulfonate. In RPMI 6410 cells NBMPR-insensitive transport accounts for only 2% of the initial rate of uridine transport. In contrast, 20% of the initial rate of transport of L1210 cells is insensitive to NBMPR, and uridine uptake over longer periods (10 min) is completely insensitive to NBMPR.     

Sodium-dependent, concentrative nucleoside transport in Walker 256 rat carcinosarcoma cells

Nucleoside transport in Walker 256 cells was reexamined using formycin B, a nonmetabolized analog of inosine. In the presence of dipyridamole to inhibit the equilibrative (facilitated diffusion) transporter previously described in these cells, the initial rate of uptake of 1 microM formycin B was 10-fold greater in Na(+)-containing medium than in Na(+)-free medium. In the presence of Na+ and dipyridamole the intracellular concentration of formycin B exceeded that in the medium within one min and was 6-fold greater than that of the medium by 5 min. Na(+)-dependent transport of formycin B was inhibited by low concentrations of inosine, but not thymidine. Furthermore, Na(+)-dependent transport of uridine, but not thymidine, was apparent in the presence of dipyridamole. These data indicate that Walker 256 cells have, in addition to the previously described equilibrative transporter, a concentrative nucleoside transporter. The specificity of this transporter appears to correspond to one of the two Na(+)-dependent transporters previously described in mouse intestinal epithelial cells.     

Genetic analysis of the 6-thiobenzylpurine binding site of the nucleoside transporter in mouse lymphoblasts

From a mutagenized population of wild-type S49 T lymphoblasts, cells were selected for their ability to survive in semisolid medium containing 0.5 mM hypoxanthine, 0.4 microM methotrexate, 30 microM thymidine, 30 microM deoxycytidine, and 30 microM p-nitrobenzyl-6-thioinosine (NBMPR), a potent inhibitor of nucleoside transport. Unlike wild-type parental cells, two mutant clones, KAB1 and KAB5, were still sensitive to nucleoside-mediated cytotoxicity in the presence of NBMPR. Comparisons of the abilities of wild-type cells, KAB1, and KAB5 cells to incorporate exogenous nucleoside to the corresponding nucleoside triphosphate indicated that nucleoside incorporation was much less sensitive to inhibition by NBMPR in the mutant cells. Rapid transport studies indicated that the mutant cell lines, unlike the wild-type parent, had acquired an NBMPR-insensitive nucleoside transport component which was similar to the NBMPR-sensitive wild-type transporter with respect to affinities for nucleosides and sensitivities toward N-ethylmaleimide and dipyridamole. Binding studies with [3H]NBMPR indicated that KAB5 cells were 70-75% deficient in the number of NBMPR binding sites, whereas KAB1 cells possessed a wild-type complement of NBMPR binding sites with wild-type binding characteristics. These data suggest that the NBMPR binding site in wild-type S49 cells is genetically distinguishable from the nucleoside carrier site and that the former may be a regulatory site.     

Mycoplasma contamination greatly enhances the apparent transport and concentrative accumulation of formycin B by mammalian cell culture

S49 mouse leukemia cells exhibit both equilibrative and Na(+)-dependent, concentrative formycin B transport. The latter represents only a minor nucleoside transport component and is detectable only when equilibrative nucleoside transport is inhibited by dipyridamole or another transport inhibitor. Thus in uncontaminated S49 cells formycin B accumulated only to slightly above the intracellular-extracellular equilibrium level. In contrast, in suspensions of S49 cells contaminated with mycoplasma, formycin B accumulated in the intracellular water space in unmodified form to 40-50-times the extracellular concentration in a dipyridamole-independent manner during 90 min of incubation at 37 degrees C. The mycoplasma active formycin B transport system was inhibited by all nucleosides tested, including thymidine and deoxycytidine, which are not substrates for the concentrative nucleoside transporter of S49 cells. Mycoplasma contamination was detected by the presence of cell-associated adenosine phosphorylase activity.     

Nucleoside transport in cultured LLC-PK1 epithelia.

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

Na(+)-dependent, active nucleoside transport in mouse spleen lymphocytes, leukemia cells, fibroblasts and macrophages, but not in equivalent human or pig cells; dipyridamole enhances nucleoside salvage by cells with both active and facilitated transport

Formycin B influx studies have shown that P388 and L1210 mouse leukemia cells, mouse L929 cells, mouse RAW 309 Cr.1 cells, LK35.2 mouse B-cell hybridoma cells and cultured mouse peritoneal macrophages express both Na(+)-dependent, active and nonconcentrative, facilitated nucleoside transport systems. In the mouse cell lines, active transport represented only a minor nucleoside transport component and was detected only by measuring formycin B uptake in the presence of dipyridamole or nitrobenzylthioinosine, strong inhibitors of facilitated, but not of active, nucleoside transport. Inhibition of facilitated transport resulted in the concentrative accumulation of formycin B in cells expressing active nucleoside transport. Concentrative formycin B accumulation was abolished by treatment of the cells with gramicidin or absence of Na+ in the extracellular medium and strongly inhibited by ATP depletion or ouabain treatment. Mouse macrophages accumulated formycin B to 70-times the extracellular concentration in the absence of dipyridamole during 90 min of incubation at 37 degrees C. Thus active transport represents a major nucleoside transport system of these cells, similarly as previously reported for mouse spleen lymphocytes. In contrast to the various types of mouse cells, active formycin B transport was not detected in human HeLa cells, human H9, Jurkat and CEM T lymphoidal cells and pig spleen lymphocytes. These cells expressed only facilitated nucleoside transport with kinetic properties similar to those of the facilitated transporters of other mammalian cells.     

Na+-dependent and -independent transport of uridine and its phosphorylation in mouse spleen cells

Rapid kinetic techniques were used to study the transport and salvage of uridine and other nucleosides in mouse spleen cells. Spleen cells express two nucleoside transport systems: (1) the non-concentrative, symmetrical, Na+-independent transporter with broad substrate specificity, which has been found in all mammalian cells and is sensitive to inhibition by dipyridamole and nitrobenzylthioinosine; and (2) a Na+-dependent nucleoside transport, which is specific for uridine and purine nucleosides and resistant to inhibition by dipyridamole and nitrobenzylthioinosine. The kinetic properties of the two transporters were determined by measuring uridine influx in ATP-depleted cells and dipyridamole-treated cells, respectively. The Michaelis-Menten constants for Na+-independent and -dependent transport were about 40 and 200 microM, respectively, but the first-order rate constants were about the same for both transport systems. Nitrobenzylthioinosine-sensitivity of the facilitated nucleoside transporter correlated with the presence of about 10,000 high-affinity (Kd = 0.6 nM) nitrobenzylthioinosine-binding sites per cell. The turnover number of the nitrobenzylthioinosine-sensitive nucleoside transporter was comparable to that of mouse P388 leukemia cells. The activation energy of this transporter was 20 kcal/mol. Entry of uridine via either of the transport routes was rapidly followed by its phosphorylation and conversion to UTP. The Michaelis-Menten constant for the in situ phosphorylation of uridine was about 50 microM and the first-order rate constants for phosphorylation and transport were about the same. The spleen cells also efficiently salvaged adenosine, adenine, and hypoxanthine, but not thymidine.     

Sodium-dependent, concentrative nucleoside transport in cultured intestinal epithelial cells

In a simple salts medium, monolayers of IEC-6 intestinal cells achieved concentrations of unmetabolized formycin B (an analog of inosine) about 6-fold higher than in the medium. Rates of formycin B influx were a saturable function of Na+ concentrations in the medium. Although IEC-6 cells possess sites with high affinity for nitrobenzylthioinosine, a potent inhibitor of equilibrative (facilitated diffusion) nucleoside transport systems in certain cell types, the inhibitor had only minor effects on formycin B uptake in IEC-6 cells, but reduced efflux of the analog from these cells. These findings indicate the joint presence in IEC-6 cells of nucleoside transporters of two types, one that is concentrative and Na+-dependent, and another that is sensitive to nitrobenzylthioinosine and apparently equilibrative.     

Recent advances in studies on biochemical and structural properties of equilibrative and concentrative nucleoside transporters

Nucleoside transporters (NT) facilitate the movement of nucleosides and nucleobases across cell membranes. NT-mediated transport is vital for the synthesis of nucleic acids in cells that lack de novo purine synthesis. Some nucleosides display biological activity and act as signalling molecules. For example, adenosine exerts a potent action on many physiological processes including vasodilatation, hormone and neurotransmitter release, platelet aggregation, and lipolysis. Therefore, carrier-mediated transport of this nucleoside plays an important role in modulating cell function, because the efficiency of the transport processes determines adenosine availability to its receptors or to metabolizing enzymes. Nucleoside transporters are also key elements in anticancer and antiviral therapy with the use of nucleoside analogues. Mammalian cells possess two major nucleoside transporter families: equilibrative (ENT) and concentrative (CNT) Na(+)-dependent ones. This review characterizes gene loci, substrate specificity, tissue distribution, membrane topology and structure of ENT and CNT proteins. Regulation of nucleoside transporters by various factors is also presented.     

Stable expression of a recombinant sodium-dependent, pyrimidine-selective nucleoside transporter (CNT1) in a transport-deficient mouse leukemia cell line.

Previous studies of nucleoside transport in mammalian cells have identified two types of activities: the equilibrative nucleoside transporters and concentrative, Na+-nucleoside cotransporters. Characterization of the concentrative nucleoside transporters has been hampered by the presence in most cells and tissues of multiple transporters with overlapping permeant specificities. With the recent cloning of cDNAs encoding rat and human members of the concentrative nucleoside transporter (CNT) family, it is now possible to study the concentrative transporters in isolation by use of functional expression systems. We report here the isolation of a nucleoside transport-deficient subline of L1210 mouse leukemia (L1210/DNC3) that is a suitable recipient for stable expression of cloned nucleoside transporter cDNAs. We have used L1210/DNC3 as the recipient in gene transfer studies to develop a stable cell line (L1210/DU5) that produces the recombinant concentrative nucleoside transporter with selectivity for pyrimidine nucleosides (CNT1) that was initially identified in rat intestine (Q.Q. Huang, S.Y. Yao, M.W. Ritzel, A.R.P. Paterson, C.E. Cass, and J.D. Young. 1994. J. Biol. Chem. 269: 17,757-17,760). L1210/DU5 was used to examine the permeant selectivity of recombinant rat CNT1 by comparing a series of nucleoside analogs with respect to (i) inhibition of inward fluxes of [3H]thymidine, (ii) initial rates of transport of 3H-analog, and (iii) cytotoxicity to L1210/DU5 versus the parental transport-deficient cell line. By all three criteria, recombinant CNT1 transported 5-fluoro-2'-deoxyuridine and 5-fluorouridine well and cytosine arabinoside poorly. Although some purine nucleosides (2'-deoxyadenosinedeoxyadeno-2'-deoxyadenosine, 7-deazaadenosine) were potent inhibitors of CNT1, they were poor permeants when uptake was measured directly by analysis of isotopic fluxes or indirectly by comparison of cytotoxicity ratios. We conclude that comparison of analog cytotoxicity to L1210/DU5 versus L1210/DNC3 is a reliable indirect predictor of transportability, suggesting that cytotoxicity assays with a panel of such cell lines, each with a different recombinant nucleoside transporter, would be a valuable tool in the development of antiviral and antitumor nucleoside analogs.     

A nucleoside transporter is functionally linked to ectonucleotidases in rat liver canalicular membrane.

Prevention of nucleoside loss in bile is physiologically desirable because hepatocytes are the main source of nucleosides for animal cells which lack de novo nucleoside biosynthesis. We have demonstrated a Na+ gradient-energized, concentrative nucleoside transport system in canalicular membrane vesicles (CMV) from rat liver by studying [3H]adenosine uptake using a rapid filtration technique. The Na(+)-dependent nucleoside transporter accepts purine, analogues of purine nucleosides and uridine; exhibits high affinity for adenosine (apparent Km, 14 microM); is not inhibited by nitrobenzylthioinosine or dipyridamole, and is present in CMV but not in rat liver sinusoidal membrane vesicles. Adenosine transport in right side-out CMV was substantially greater than with inside-out CMV. CMV also contain abundant ecto-ATPase and ecto-AMPase (5'-nucleotidase). These ectoenzymes were shown to degrade nucleotides into nucleosides which were conserved by the Na(+)-dependent nucleoside transport system.