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.     

Expression of the high-affinity purine nucleobase transporter in mutant mouse S49 cells does not require a functional wild-type nucleoside-nucleobase transporter.

A novel type of somatic mutation that causes the expression of a high-affinity purine base permease (B. Aronow, D. Toll, J. Patrick, P. Hollingsworth, K. McCartan, and B. Ullmann, Mol. Cell Biol. 6:2957-2962, 1986) has been inserted into nucleoside transport-deficient S49 cells. Two classes of mutants expressing this nucleobase permease were generated. The first, as exemplified by the AE1HADPAB2 cell line, possessed an augmented capacity to transport low concentrations of the three purine bases, hypoxanthine, guanine, and adenine. The second class of mutants, as typified by the AE1HADPAB5 clone, possessed an augmented capability to translocate low levels of hypoxanthine and guanine, but not adenine. Neither the AE1HADPAB2 nor the AE1HADPAB5 cells could transport nucleosides, suggesting that the expression of the high-affinity base transporter did not reverse the mutation in the nucleoside transport system. The transport of purine bases by both AE1HADPAB2 and AE1HADPAB5 cells was much less sensitive than that by wild-type cells to inhibition by dipyridamole, 4-nitrobenzylthionosine, and N-ethylmaleimide, potent inhibitors of nucleoside and nucleobase transport in wild-type S49 cells. Fusion of the AE1HADPAB2 and AE1HADPAB5 cell lines with wild-type cells indicated that the expression of the high-affinity base transporter behaved in a dominant fashion, while the nucleoside transport deficiency was a recessive trait. These data suggest that the high-affinity purine base transporter of mutant cells and the nucleoside transport function of wild-type cells are products of different genes and that expression of the former probably requires the unmasking or alteration of a specific genetic locus that is silent or different in wild-type cells.     

Genetic demonstration of bidirectionality in the high affinity purine base transporter of mutant mouse S49 cells

A mutant cell line was selected from wild type S49 lymphoblasts that expressed a novel high affinity purine base transport system not found in parental cells or any other mammalian cell line (Aronow, B., Toll, D., Patrick, J., Hollingsworth, P., McCartan, K., and Ullman, B. (1986) Mol. Cell. Biol. 6, 2957-2962). In order to determine whether this nucleobase transport system was bidirectional, mutant cell lines possessing this high affinity base transport capability were derived from a nucleoside transport-deficient derivative of an adenylosuccinate synthetase-deficient S49 cell line. The resulting progeny excreted significantly greater amounts of purine into the cell culture medium than parental cells. This purine was identified as hypoxanthine. These results demonstrate genetically that the high affinity purine base transport system can mediate both the influx and efflux of hypoxanthine.     

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.     

Incomplete nucleoside transport deficiency with increased hypoxanthine transport capability in mutant T-lymphoblastoid cells.

From a mutagenized population of wild-type mouse (S49) T-lymphoma cells, a clone, 80-5D2, was isolated in a single step by virtue of its ability to survive in 80 nM 5-fluorouridine. Unlike previously isolated nucleoside transport-deficient cell lines (A. Cohen, B. Ullman, and D. W. Martin, Jr., J. Biol. Chem. 254:112-116, 1979), 80-5D2 cells were only slightly less sensitive to growth inhibition by a variety of cytotoxic nucleosides and were capable of proliferating in hypoxanthine-amethopterin-thymidine-containing medium. The molecular basis for the phenotype of 80-5D2 cells was incomplete deficiency in the ability of the mutant cells to translocate nucleosides across the plasma membrane. Interestingly, mutant cells were more capable than wild-type cells of transporting the nucleobase hypoxanthine. Residual transport of adenosine into 80-5D2 cells was just as sensitive to inhibition by nucleosides and more sensitive to inhibition by hypoxanthine than that in wild-type cells, indicating that the phenomena of ligand binding and translocation can be uncoupled genetically. The 80-5D2 cells lacked cell surface binding sites for the potent inhibitor of nucleoside transport p-nitrobenzylthioinosine (NBMPR) and, consequently, were largely resistant to the physiological effects of NBMPR. However, the altered transporter retained its sensitivity to dipyridamole, another inhibitor of nucleoside transport. The biochemical phenotype of the 80-5D2 cell line supports the hypothesis that the determinants that comprise the nucleoside carrier site, the hypoxanthine carrier site, the NBMPR binding site, and the dipyridamole binding site of the nucleoside transport function of mouse S49 cells are genetically distinguishable.     

Role of the nucleoside transport function in the transport and salvage of purine nucleobases

Genetic deficiencies in the nucleoside transport function markedly altered the abilities of cultured mutant S49 T lymphoblasts to transport, incorporate, and salvage exogenous hypoxanthine. The concentrations of exogenous hypoxanthine required to reverse azaserine toxicity and replenish azaserine-depleted nucleoside triphosphate pools in AE1 cells, a nucleoside transport-deficient clone, were about 10-fold higher than those required for wild type cells. In a similar fashion, guanine could reverse mycophenolic acid toxicity in wild type but not in AE1 cells. Surprisingly, a second nucleoside transport-deficient clone, 80-5D2, which had lost 80-90% of its ability to transport nucleosides, required lower hypoxanthine concentrations than the wild type parent to reverse these azaserine-mediated effects. The addition of submicromolar concentrations of either p-nitrobenzylthioinosine or dipyridamole, two potent inhibitors of nucleoside transport, to wild type cells mimicked the phenotype of the AE1 cells with respect to hypoxanthine. AE1 cells or p-nitrobenzylthioinosine-treated wild type cells could only transport hypoxanthine at 10-25% the rate of untreated wild type cells, whereas 80-5D2 cells could transport hypoxanthine more efficiently. Adenine transport was also diminished in AE1 and FURD-80-3-6 cells, but not to sufficiently low levels to interfere with their ability to salvage adenine to overcome azaserine toxicity. These studies on S49 cells altered in their nucleoside transport capacity provide powerful genetic evidence that purine nucleobases share a common transport function with nucleosides in these mammalian T lymphoblasts.     

Nucleoside and nucleobase transporters of primary human cardiac microvascular endothelial cells: characterization of a novel nucleobase transporter

Levels of cardiovascular active metabolites, like adenosine, are regulated by nucleoside transporters of endothelial cells. We characterized the nucleoside and nucleobase transport capabilities of primary human cardiac microvascular endothelial cells (hMVECs). hMVECs accumulated 2-[3H]chloroadenosine via the nitrobenzylmercaptopurine riboside-sensitive equilibrative nucleoside transporter 1 (ENT1) at a V(max) of 3.4 +/- 1 pmol.microl(-1).s(-1), with no contribution from the nitrobenzylmercaptopurine riboside-insensitive ENT2. Inhibition of 2-chloroadenosine uptake by ENT1 blockers produced monophasic inhibition curves, which are also compatible with minimal ENT2 expression. The nucleobase [3H]hypoxanthine was accumulated within hMVECs (K(m) = 96 +/- 37 microM; V(max) = 1.6 +/- 0.3 pmol.microl(-1).s(-1)) despite the lack of a known nucleobase transport system. This novel transporter was dipyridamole-insensitive but could be inhibited by adenine (K(i) = 19 +/- 7 microM) and other purine nucleobases, including chemotherapeutic analogs. A variety of other cell types also expressed the nucleobase transporter, including the nucleoside transporter-deficient PK(15) cell line (PK15NTD). Further characterization of [3H]hypoxanthine uptake in the PK15NTD cells showed no dependence on Na(+) or H(+). PK15NTD cells expressing human ENT2 accumulated 4.5-fold more [3H]hypoxanthine in the presence of the ENT2 inhibitor dipyridamole than did PK15NTD cells or hMVECs, suggesting trapping of ENT2-permeable metabolites. Understanding the nucleoside and nucleobase transporter profiles in the vasculature will allow for further study into their roles in pathophysiological conditions such as hypoxia or ischemia.     

Altered nucleoside transporters in mammalian cells selected for resistance to the physiological effects of inhibitors of nucleoside transport

From a mutagenized population of wild type S49 T lymphoma cells, clones were generated that were resistant to the physiological effects of the potent inhibitor of nucleoside transport, 4-nitrobenzyl-6-thioinosine (NBMPR). These 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, in the presence of 30 microM NBMPR. NBMPR protected wild type cells from the effects of a spectrum of cytotoxic nucleosides, whereas 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 and mutant cells to incorporate exogenous nucleoside to the corresponding nucleoside triphosphate indicated that the KAB1 and KAB5 mutant cells were refractory to normal inhibition by NBMPR. Moreover, rapid transport studies indicated that mutant cells, unlike wild type parental cells, had acquired a substantial NBMPR-insensitive nucleoside transport component. 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. These data suggest that the NBMPR binding site in wild type S49 cells is genetically distinguishable from the nucleoside carrier site.     

Nucleobase transport by human equilibrative nucleoside transporter 1 (hENT1)

The human equilibrative nucleoside transporters hENT1 and hENT2 (each with 456 residues) are 40% identical in amino acid sequence and contain 11 putative transmembrane helices. Both transport purine and pyrimidine nucleosides and are distinguished functionally by a difference in sensitivity to inhibition by nanomolar concentrations of nitrobenzylmercaptopurine ribonucleoside (NBMPR), hENT1 being NBMPR-sensitive. Previously, we used heterologous expression in Xenopus oocytes to demonstrate that recombinant hENT2 and its rat ortholog rENT2 also transport purine and pyrimidine bases, h/rENT2 representing the first identified mammalian nucleobase transporter proteins (Yao, S. Y., Ng, A. M., Vickers, M. F., Sundaram, M., Cass, C. E., Baldwin, S. A., and Young, J. D. (2002) J. Biol. Chem. 277, 24938-24948). The same study also revealed lower, but significant, transport of hypoxanthine by h/rENT1. In the present investigation, we have used the enhanced Xenopus oocyte expression vector pGEMHE to demonstrate that hENT1 additionally transports thymine and adenine and, to a lesser extent, uracil and guanine. Fluxes of hypoxanthine, thymine, and adenine by hENT1 were saturable and inhibited by NBMPR. Ratios of V(max) (pmol/oocyte · min(-1)):K(m) (mm), a measure of transport efficiency, were 86, 177, and 120 for hypoxantine, thymine, and adenine, respectively, compared with 265 for uridine. Hypoxanthine influx was competitively inhibited by uridine, indicating common or overlapping nucleobase and nucleoside permeant binding pockets, and the anticancer nucleobase drugs 5-fluorouracil and 6-mercaptopurine were also transported. Nucleobase transport activity was absent from an engineered cysteine-less version hENT1 (hENT1C-) in which all 10 endogenous cysteine residues were mutated to serine. Site-directed mutagenesis identified Cys-414 in transmembrane helix 10 of hENT1 as the residue conferring nucleobase transport activity to the wild-type transporter.     

Purine nucleobase transport in human erythrocytes. Reinvestigation with a novel "inhibitor-stop" assay

A novel "inhibitor-stop" method for the determination of initial rates of purine nucleobase transport in human erythrocytes has been developed, based on the addition of seven assay volumes of cold 19 mM papaverine to terminate influx. In view of our finding that the initial velocities of adenine, guanine, and hypoxanthine influx into human erythrocytes were linear for only 4-6 s at 37 degrees C, the present method has been used to reexamine the kinetics of purine nucleobase transport in these cells. Initial influx rates of all three purine nucleobases were shown to be the result of concurrent facilitated and nonfacilitated diffusion. The nonfacilitated influx rates could be estimated either from the linear concentration dependence of nucleobase influx at high concentrations of permeant or from residual influx rates which were not inhibited by the presence of co-permeants. Appropriate corrections for nonfacilitated diffusion were made to the influx rates observed at low nucleobase concentrations. Kinetic analyses indicated that adenine (Km = 13 +/- 1 microM, n = 7), guanine (Km = 37 +/- 2 microM, n = 5), and hypoxanthine (Km = 180 +/- 12 microM, n = 6) were mutually competitive substrates for transport. The Ki values obtained with each nucleobase as an inhibitor of the influx of the other nucleobases were similar to their respective Km values for influx. Furthermore, the transport of the purine nucleobases was not inhibited by nucleosides (uridine, inosine) or by inhibitors of nucleoside transport (6-[(4-nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine, dilazep, dipyridamole). It is concluded that all three purine nucleobases share a common facilitated transport system in human erythrocytes which is functionally distinct from the nucleoside transporter.     

Genetic demonstration that the mutationally expressed nucleobase transporter of mouse S49 cells is nonconcentrative

Somatic cell genetic analysis of purine base transporters in mouse S49 cells has demonstrated the existence of a unique high-affinity purine base transporter, which is mutationally expressed and is not found in wild-type S49 cells or any other cells of the animal kingdom (B. Aronow, et al. (1986) Mol. Cell. Biol. 6, 2957). In order to determine whether this nucleobase transport system is active and concentrative, a secondary mutation in hypoxanthine-guanine phosphoribosyltransferase (HGPRTase) was inserted into the cell line expressing this novel base transporter. The HGPRTase-deficient cells were capable of transporting hypoxanthine at increased rates but did not accumulate the base to concentrations in excess of that in the culture medium. Moreover, neither sodium azide nor ouabain had significant effects on hypoxanthine transport rates, indicating that energy metabolism and the maintenance of a sodium gradient were not required for transport function. These studies suggest that the novel mutationally expressed base transporter is independent of subsequent metabolism and does not require energy or a functioning Na+-K+-dependent ATPase activity.     

Acyclovir transport into human erythrocytes

The mechanism of transport of the antiviral agent acyclovir (ACV) into human erythrocytes has been investigated. Initial velocities of ACV influx were determined with an "inhibitor-stop" assay that used papaverine to inhibit ACV influx rapidly and completely. ACV influx was nonconcentrative and appeared to be rate-saturable with a Km of 260 +/- 20 microM (n = 8). However, two lines of evidence indicate that ACV permeates the erythrocyte membrane by means other than the nucleoside transport system: 1) potent inhibitors (1.0 microM) of nucleoside transport (dipyridamole, 6-[(4-nitrobenzyl)thio]-9-beta-D-ribofuranosylpurine, and dilazep) had little (less than 8% inhibition) or no effect upon the influx of 5.0 microM ACV; and 2) a 100-fold molar excess of several purine and pyrimidine nucleosides had no inhibitory effect upon the influx of 1.0 microM ACV. However, ACV transport was inhibited competitively by adenine (Ki = 9.5 microM), guanine (Ki = 25 microM), and hypoxanthine (Ki = 180 microM). Conversely, ACV was a competitive inhibitor (Ki = 240-280 microM) of the transport of adenine (Km = 13 microM), guanine (Km = 37 microM), and hypoxanthine (Km = 180 microM). Desciclovir and ganciclovir, two compounds related structurally to ACV, were also found to be competitive inhibitors of acyclovir influx (Ki = 1.7 and 1.5 mM, respectively). These results indicate that ACV enters human erythrocytes chiefly via the same nucleobase carrier that transports adenine, guanine, and hypoxanthine.     

Interconversion and uptake of nucleotides, nucleosides, and purine bases by the marine bacterium MB22.

Whole cells and isolated membranes of the marine bacterium MB22 converted nucleotides present in the external medium rapidly into nucleosides and then into bases. Nucleosides and purine bases formed were taken up by distinct transport systems. We found a high-affinity common transport system for adenine, guanine, and hypoxanthine, with a Km of 40 nM. This system was inhibited noncompetitively by purine nucleosides. In addition, two transport systems for nucleosides were present: one for guanosine with a Km of 0.8 microM and another one for inosine and adenosine with a Km of 1.4 microM. The nucleoside transport systems exhibited both mixed and noncompetitive inhibition by different nucleosides other than those translocated; purine and pyrimidine bases had no effect. The transport of nucleosides and purine bases was inhibited by dinitrophenol or azide, thus suggesting that transport is energy dependent. Inside the cell all of the substrates were converted mainly into guanosine, xanthine, and uric acid, but also anabolic products, such as nucleotides and nucleic acids, could be found.     

S49 mouse lymphoma cells are deficient in hypoxanthine transport

The rate of uptake of hypoxanthine in S49 cells was only about 2-5% of the rate of hypoxanthine transport observed in many other types of mammalian cells, and of the rate of uridine transport in this and other cell types. Part of the slow entry of hypoxanthine seems to be due to non-mediated permeation, but the remainder is saturable, strongly inhibited by uridine, nitrobenzylthioinosine and dipyridamole and not detectable in a nucleoside-transport-deficient mutant of S49 cells (AE1). The inhibition of hypoxanthine transport in S49 cells by nitrobenzylthioinosine resembles the inhibition of nucleoside transport in these and other mammalian cells, whereas it contrasts with the resistance of hypoxanthine transport to nitrobenzylthioinosine in all types of mammalian cells that have been investigated. We conclude that S49 cells lack the hypoxanthine transport system common to other types of cells and that hypoxanthine entry into these cells is mediated, although very inefficiently, by the nucleoside transporter. In contrast, adenine transport in S49 and AE1 cells was comparable to that in other types of cells.     

Genetic studies on the role of the nucleoside transport function in nucleoside efflux, the inosine cycle, and purine biosynthesis.

A mutant clone (AU-100) which is 90% deficient in adenylosuccinate synthetase activity was characterized from wild-type murine S49 T-lymphoma cells. This AU-100 cell line and its hypoxanthine-guanine phosphoribosyltransferase-deficient derivative, AUTG-50B, overproduce purines severalfold and excrete massive amounts of inosine into the culture medium (Ullman et al., Proc. Natl. Acad. Sci. U.S.A. 79:5127-5131, 1982). We introduced a mutation into both of these cell lines which make them incapable of taking up nucleosides from the culture medium. The genetic deficiency in nucleoside transport prevents the adenylosuccinate synthetase-deficient AU-100 cells from excreting inosine. Because of an extremely efficient intracellular inosine salvage system, the nucleoside transport-deficient AU-100 cells also no longer overproduce purines. AUTG-50B cells which have been made genetically deficient in nucleoside transport still overproduce purines but excrete hypoxanthine rather than inosine. These studies demonstrate genetically that nucleoside transport and nucleoside efflux share a common component and that nucleoside transport has an important regulatory function which profoundly affects the rates of purine biosynthesis and purine salvage.     

Identification and characterisation of high affinity nucleoside and nucleobase transporters in Toxoplasma gondii

The protozoan parasite Toxoplasma gondii depends upon salvaging the purines that it requires. We have re-analysed purine transport in T. gondii and identified novel nucleoside and nucleobase transporters. The latter transports hypoxanthine (TgNBT1; K(m)=0.91+/-0.19 microM) and is inhibited by guanine and xanthine: it is the first high affinity nucleobase transporter to be identified in an apicomplexan parasite. The previously reported nucleoside transporter, TgAT1, is low affinity with K(m) values of 105 and 134 microM for adenosine and inosine, respectively. We have now identified a second nucleoside transporter, TgAT2, which is high affinity and inhibited by adenosine, inosine, guanosine, uridine and thymidine (K(m) values 0.28-1.5 microM) as well as cytidine (K(i)=32 microM). TgAT2 also recognises several nucleoside analogues with therapeutic potential. We have investigated the basis for the broad specificity of TgAT2 and found that hydrogen bonds are formed with the 3' and 5' hydroxyl groups and that the base groups are bound through H-bonds with either N3 of the purine ring or N(3)H of the pyrimidine ring, and most probably pi-pi-stacking as well. The identification of these high affinity purine nucleobase and nucleoside transporters reconciles for the first time the low abundance of free nucleosides and nucleobases in the intracellular environment with the efficient purine salvage carried out by T. gondii.     

Genetic analysis of 2',3'-dideoxycytidine incorporation into cultured human T lymphoblasts

In order to analyze the cellular determinants that mediate the action of 2',3'-dideoxycytidine, the growth inhibitory and cytotoxic effects and the metabolism of the dideoxynucleoside were examined in wild type human CEM T lymphoblasts and in mutant populations of CEM cells that were genetically deficient in either nucleoside transport or deoxycytidine kinase activity. Whereas 2',3'-dideoxycytidine at a concentration of 5 microM inhibited growth of the wild type CEM parental strain by 50%, two nucleoside transport-deficient clones were 4-fold resistant to the pyrimidine analog. The deoxycytidine kinase-deficient cell line was virtually completely resistant to growth inhibition by the dideoxynucleoside at a concentration of 1024 microM. An 80% diminished rate of 2',3'-[5,6-3H]dideoxycytidine influx into the two nucleoside transport-deficient lines could account for their resistance to the dideoxynucleoside, while the resistance of the deoxycytidine kinase-deficient cells to 2',3'-dideoxycytidine toxicity could be explained by a virtually complete failure to incorporate 2',3'-[5,6-3H]dideoxycytidine in situ. Two potent inhibitors of mammalian nucleoside transport, 4-nitrobenzylthioinosine and dipyridamole, mimicked the effects of a genetic deficiency in nucleoside transport with respect to 2',3'-dideoxycytidine toxicity and incorporation. These data indicate that the intracellular metabolism of 2',3'-dideoxycytidine in CEM cells is initiated by the nucleoside transport system and the cellular deoxycytidine kinase activity.     

A purine-selective nucleobase/nucleoside transporter in PK15NTD cells

Nucleoside and nucleobase transporters are important for salvage of purines and pyrimidines and for transport of their analog drugs into cells. However, the pathways for nucleobase translocation in mammalian cells are not well characterized. We identified an Na-independent purine-selective nucleobase/nucleoside transport system in the nucleoside transporter-deficient PK15NTD cells. This transport system has 1,000-fold higher affinity for nucleobases than nucleosides with K(m) values of 2.5 +/- 0.7 microM for [(3)H]adenine, 6.4 +/- 0.5 microM for [(3)H]guanine, 1.1 +/- 0.1 mM for [(3)H]guanosine, and 4.2 +/- 0.5 mM [(3)H]adenosine. The uptake of [(3)H]guanine (0.05 microM) was inhibited by other nucleobases and nucleobase analog drugs (at 0.5-1 mM in the order of potency): 6-mercaptopurine = thioguanine = guanine > adenine > thymine = fluorouracil = uracil. Cytosine and methylcytosine had no effect. Nucleoside analog drugs with modification at 2' and/or 5 positions (all at 1 mM) were more potent than adenosine in competing the uptake of [(3)H]guanine: 2-chloro-2'-deoxyadenosine > 2-chloroadenosine > 2'3'-dideoxyadenosine = 2'-deoxyadenosine > 5-deoxyadenosine > adenosine. 2-Chloro-2'-deoxyadenosine and 2-chloroadenosine inhibited [(3)H]guanine uptake with IC(50) values of 68 +/- 5 and 99 +/- 10 microM, respectively. The nucleobase/nucleoside transporter was resistant to nitrobenzylthioinosine {6-[(4-nitrobenzyl) thiol]-9-beta-D-ribofuranosylpurine}, dipyridamole, and dilazep, but was inhibited by papaverine, the organic cation transporter inhibitor decynium-22 (IC(50) of approximately 1 microM), and by acidic pH (pH = 5.5). In conclusion, we have identified a mammalian purine-selective nucleobase/nucleoside transporter with high affinity for purine nucleobases. This transporter is potentially important for transporting naturally occurring purines and purine analog drugs into cells.     

Thymidine incorporation in nucleoside transport-deficient lymphoma cells

Nucleoside transport deficiency in mammalian cells is associated with an inability to transport most nucleosides, growth resistance to a spectrum of cytotoxic nucleosides, and a loss of binding sites for 4-nitrobenzylthioinosine (NBMPR), a potent inhibitor of nucleoside transport. The nucleoside transport-deficient S49 T lymphoma cell line, AE1, however, was almost as capable of incorporating thymidine into TTP as the wild type parent provided thymidine was administered at a sufficiently high concentration. Consequently, AE1 cells were just as sensitive as wild type cells to the toxicity of high thymidine concentrations. In contrast, AE1 cells were highly resistant to almost all other cytotoxic nucleosides including the thymidine analogs, 5-bromodeoxyuridine and 5-fluoro-2'-deoxyuridine 5'-monophosphate. Despite having demonstrable ability to accumulate TTP, AE1 cells were unable to grow on hypoxanthine-amethopterin-thymidine (HAT)-containing medium. This was due to their inability to accumulate sufficient TTP from the low concentrations of thymidine present in HAT medium. AE1 cells possessed an incomplete thymidine transport deficiency, the extent of which was concentration dependent. The residual capacity for thymidine transport present in AE1 cells was insensitive to inhibition by 4-nitrobenzylthioinosine and could account both for their inability to grow on HAT medium and their sensitivity to cytotoxic concentrations of thymidine. Another nucleoside transport-deficient cell line, FURD-80-3-6, was similar to the AE1 cell line in its growth phenotype and NBMPR-binding site deficiency but differed in its decreased growth sensitivity to thymidine. That nucleoside transport deficiencies may vary in their completeness for different nucleosides has significance for the mechanism by which a single transporter can recognize a wide variety of nucleosides.     

A comprehensive model of purine uptake by the malaria parasite Plasmodium falciparum: identification of four purine transport activities in intraerythrocytic parasites

Plasmodium falciparum is incapable of de novo purine biosynthesis, and is absolutely dependent on transporters to salvage purines from the environment. Only one low-affinity adenosine transporter has been characterized to date. In the present study we report a comprehensive study of purine nucleobase and nucleoside transport by intraerythrocytic P. falciparum parasites. Isolated trophozoites expressed (i) a high-affinity hypoxanthine transporter with a secondary capacity for purine nucleosides, (ii) a separate high-affinity transporter for adenine, (iii) a low-affinity adenosine transporter, and (iv) a low-affinity/high-capacity adenine carrier. Hypoxanthine was taken up with 12-fold higher efficiency than adenosine. Using a parasite clone with a disrupted PfNT1 (P. falciparum nucleoside transporter 1) gene we found that the high-affinity hypoxanthine/nucleoside transport activity was completely abolished, whereas the low-affinity adenosine transport activity was unchanged. Adenine transport was increased, presumably to partly compensate for the loss of the high-affinity hypoxanthine transporter. We thus propose a model for purine salvage in P. falciparum, based on the highly efficient uptake of hypoxanthine by PfNT1 and a high capacity for purine nucleoside uptake by a lower affinity carrier.