Mutation of residue 33 of human equilibrative nucleoside transporters 1 and 2 alters sensitivity to inhibition of transport by dilazep and dipyridamole.

Human equilibrative nucleoside transporters (hENT) 1 and 2 differ in that hENT1 is inhibited by nanomolar concentrations of dipyridamole and dilazep, whereas hENT2 is 2 and 3 orders of magnitude less sensitive, respectively. When a yeast expression plasmid containing the hENT1 cDNA was randomly mutated and screened by phenotypic complementation in Saccharomyces cerevisiae to identify mutants with reduced sensitivity to dilazep, clones with a point mutation that converted Met33 to Ile (hENT1-M33I) were obtained. Characterization of the mutant protein in S. cerevisiae and Xenopus laevis oocytes revealed that the mutant had less than one-tenth the sensitivity to dilazep and dipyridamole than wild type hENT1, with no change in nitrobenzylmercaptopurine ribonucleoside (NBMPR) sensitivity or apparent uridine affinity. To determine whether the reciprocal mutation in hENT2 (Ile33 to Met) also altered sensitivity to dilazep and dipyridamole, hENT2-I33M was created by site-directed mutagenesis. Although the resulting mutant (hENT2-I33M) displayed >10-fold higher dilazep and dipyridamole sensitivity and >8-fold higher uridine affinity compared with wild type hENT2, it retained insensitivity to NBMPR. These data established that mutation of residue 33 (Met versus Ile) of hENT1 and hENT2 altered the dilazep and dipyridamole sensitivities in both proteins, suggesting that a common region of inhibitor interaction has been identified.     

Mutation of Trp29 of human equilibrative nucleoside transporter 1 alters affinity for coronary vasodilator drugs and nucleoside selectivity

hENT1 (human equilibrative nucleoside transporter 1) is inhibited by nanomolar concentrations of various structurally distinct coronary vasodilator drugs, including dipyridamole, dilazep, draflazine, soluflazine and NBMPR (nitrobenzylmercaptopurine ribonucleoside). When a library of randomly mutated hENT1 cDNAs was screened using a yeast-based functional complementation assay for resistance to dilazep, a clone containing the W29G mutation was identified. Multiple sequence alignments revealed that this residue was highly conserved. Mutations at Trp29 were generated and tested for adenosine transport activity and inhibitor sensitivity. Trp29 mutations significantly reduced the apparent V(max) and/or increased the apparent K(m) values for adenosine transport. Trp29 mutations increased the IC50 values for hENT1 inhibition by dipyridamole, dilazep, NBMPR, soluflazine and draflazine. NBMPR and soluflazine displayed remarkably similar trends, with large aromatic substitutions at residue 29 resulting in the lowest IC50 values, suggesting that both drugs could interact via ring-stacking interactions with Trp29. The W29T mutant displayed a selective loss of pyrimidine nucleoside transport activity, which contrasts with the previously identified L442I mutant that displayed a selective loss of purine nucleoside transport. W29T, L442I and the double mutant W29T/L442I were characterized kinetically for nucleoside transport activity. A helical wheel projection of TM (transmembrane segment) 1 suggests that Trp29 is positioned close to Met33, implicated previously in nucleoside and inhibitor recognition, and that both residues line the permeant translocation pathway. The data also suggest that Trp29 forms part of, or lies close to, the binding sites for dipyridamole, dilazep, NBMPR, soluflazine and draflazine.     

Functional redundancy of two nucleoside transporters of the ENT family (CeENT1, CeENT2) required for development of Caenorhabditis elegans

The genome of Caenorhabditis elegans encodes multiple homologues of the two major families of mammalian equilibrative and concentrative nucleoside transporters. As part of a programme aimed at understanding the biological rationale underlying the multiplicity of eukaryote nucleoside transporters, we have now demonstrated that the nematode genes ZK809.4 (ent-1) and K09A9.3 (ent-2) encode equilibrative transporters, which we designate CeENT1 and CeENT2 respectively. These transporters resemble their human counterparts hENT1 and hENT2 in exhibiting similar broad permeant specificities for nucleosides, while differing in their permeant selectivities for nucleobases. They are insensitive to the classic inhibitors of mammalian nucleoside transport, nitrobenzylthioinosine, dilazep and draflazine, but are inhibited by the vasoactive drug dipyridamole. Use of green fluorescent protein reporter constructs indicated that the transporters are present in a limited number of locations in the adult, including intestine and pharynx. Their potential roles in these tissues were explored by using RNA interference to disrupt gene expression. Although disruption of ent-1 or ent-2 expression alone had no effect, simultaneous disruption of both genes yielded pronounced developmental defects involving the intestine and vulva.     

Residues 334 and 338 in transmembrane segment 8 of human equilibrative nucleoside transporter 1 are important determinants of inhibitor sensitivity, protein folding, and catalytic turnover

Equilibrative nucleoside transporters (ENTs) are important for the metabolic salvage of nucleosides and the cellular uptake of antineoplastic and antiviral nucleoside analogs. Human equilibrative nucleoside transporter 1 (hENT1) is inhibited by nanomolar concentrations of structurally diverse compounds, including dipyridamole, dilazep, nitrobenzylmercaptopurine ribonucleoside (NBMPR), draflazine, and soluflazine. Random mutagenesis and screening by functional complementation for inhibitor-resistant mutants in yeast revealed mutations at Phe-334 and Asn-338. Both residues are predicted to lie in transmembrane segment 8 (TM 8), which contains residues that are highly conserved in the ENT family. F334Y displayed increased V(max) values that were attributed to increased rates of catalytic turnover, and N338Q and N338C displayed altered membrane distributions that appeared to be because of protein folding defects. Mutations of Phe-334 or Asn-338 impaired interactions with dilazep and dipyridamole, whereas mutations of Asn-338 impaired interactions with draflazine and soluflazine. A helical wheel projection of TM 8 predicted that Phe-334 and Asn-338 lie in close proximity to other highly conserved and/or hydrophilic residues, suggesting that they form part of a structurally important region that influences interactions with inhibitors, protein folding, and rates of conformational change during the transport cycle.     

Functional and molecular characterization of nucleobase transport by recombinant human and rat equilibrative nucleoside transporters 1 and 2. Chimeric constructs reveal a role for the ENT2 helix 5-6 region in nucleobase translocation

The human (h) and rat (r) equilibrative (Na(+)-independent) nucleoside transporters (ENTs) hENT1, rENT1, hENT2, and rENT2 belong to a family of integral membrane proteins with 11 transmembrane domains (TMs) and are distinguished functionally by differences in sensitivity to inhibition by nitrobenzylthioinosine and coronary vasoactive drugs. Structurally, the proteins have a large glycosylated loop between TMs 1 and 2 and a large cytoplasmic loop between TMs 6 and 7. In the present study, hENT1, rENT1, hENT2, and rENT2 were produced in Xenopus laevis oocytes and investigated for their ability to transport pyrimidine and purine nucleobases. hENT2 and rENT2 efficiently transported radiolabeled hypoxanthine, adenine, guanine, uracil, and thymine (apparent K(m) values 0.7-2.6 mm), and hENT2, but not rENT2, also transported cytosine. These findings were independently confirmed by hypoxanthine transport experiments with recombinant hENT2 produced in purine-cytosine permease (FCY2)-deficient Saccharomyces cerevisiae and provide the first direct demonstration that the ENT2 isoform is a dual mechanism for the cellular uptake of nucleosides and nucleobases, both of which are physiologically important salvage metabolites. In contrast, recombinant hENT1 and rENT1 mediated negligible oocyte fluxes of hypoxanthine relative to hENT2 and rENT2. Chimeric experiments between rENT1 and rENT2 using splice sites at rENT1 residues 99 (end of TM 2), 171 (between TMs 4 and 5), and 231 (end of TM 6) identified TMs 5-6 of rENT2 (amino acid residues 172-231) as a determinant of nucleobase transport activity, suggesting that this domain forms part(s) of the ENT2 substrate translocation channel.     

A single glycine mutation in the equilibrative nucleoside transporter gene, hENT1, alters nucleoside transport activity and sensitivity to nitrobenzylthioinosine

The human equilibrative nucleoside transporter, hENT1, which is sensitive to inhibition by nitrobenzylthioinosine (NBMPR), is expressed in a wide variety of tissues. hENT1 is involved in the uptake of natural nucleosides, including regulation of the physiological effects of extracellular adenosine, and transports nucleoside drugs used in the treatment of cancer and viral diseases. Structure-function studies have revealed that transmembrane domains (TMD) 3 through 6 of hENT1 may be involved in binding of nucleosides. We have hypothesized that amino acid residues within TMD 3-6, which are conserved across equilibrative transporter sequences from several species, may have a critical role in the binding and transport of nucleosides. Therefore, we explored the role of point mutations of two conserved glycine residues, at positions 179 and 184 located in transmembrane domain 5 (TMD 5), using a GFP-tagged hENT1 in a yeast nucleoside transporter assay system. Mutations of glycine 179 to leucine, cysteine, or valine abolished transporter activity without affecting the targeting of the transporter to the plasma membrane, whereas more conservative mutations such as glycine to alanine or serine preserved both targeting to the plasma membrane and transport activity. Similar point mutations at glycine 184 resulted in poor targeting of hENT1 to the plasma membrane and little or no detectable functional activity. Uridine transport by G179A mutant was significantly lower (p < 0.05) and less sensitive (p < 0.05) to inhibition by NBMPR when compared to the wild-type transporter (IC(50) 7.7 +/- 0.8 nM versus 46 +/- 14.6 nM). Based on these data, we conclude that when hENT1 is expressed in yeast, glycine 179 is critical not only to the ability of hENT1 to transport uridine but also as a determinant of hENT1 sensitivity to NBMPR. In contrast, glycine 184 is likely important in targeting the transporter to the plasma membrane. This is the first identification and characterization of a critical amino acid residue of hENT1 that is important in both nucleoside transporter function and sensitivity to inhibition by NBMPR.     

Functional analysis of site-directed glycosylation mutants of the human equilibrative nucleoside transporter-2

Protein glycosylation is important for nucleoside transport, and this has been demonstrated for the human equilibrative nucleoside transporter-1 (hENT1). It is not known whether glycosylation affects the functions of hENT2 or where hENT2 is glycosylated. We address these questions using N-glycosylation mutants (N48D, N57D, and N48/57D) and demonstrate that hENT2 is glycosylated at Asn(48) and Asn(57). Our results show that although the apparent affinities for [3H]uridine and [3H]cytidine of the mutants were indistinguishable from those of the wild-type protein, N-glycosylation was required for efficient targeting of hENT2 to the plasma membrane. All mutants had a two- to threefold increase in IC(50) for dipyridamole. N57D and N48/57D, but not N48D, also had a twofold increase in IC(50) for NBMPR. We conclude that the relative insensitivity of hENT2 to inhibitors is primarily due to its primary structure and not to glycosylation. Glycosylation modulates hENT1 function, but is not required for hENT2.     

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.     

Molecular determinants of substrate selectivity of a novel organic cation transporter (PMAT) in the SLC29 family

Plasma membrane monoamine transporter (PMAT or ENT4) is a newly cloned transporter assigned to the equilibrative nucleoside transporter (ENT) family (SLC29). Unlike ENT1-3, PMAT mainly functions as a polyspecific organic cation transporter. In this study, we investigated the molecular mechanisms underlying the unique substrate selectivity of PMAT. By constructing chimeras between human PMAT and ENT1, we showed that a chimera consisting of transmembrane domains (TM) 1-6 of PMAT and TM7-11 of hENT1 behaved like PMAT, transporting 1-methyl-4-phenylpyridinium (MPP+, an organic cation) but not uridine (a nucleoside), suggesting that TM1-6 contains critical domains responsible for substrate recognition. To identify residues important for the cation selectivity of PMAT, 10 negatively charged residues were chosen and substituted with alanine. Five of the alanine mutants retained PMAT activity, and four were non-functional due to impaired targeting to the plasma membrane. However, alanine substitution at Glu(206) in TM5 abolished PMAT activity without affecting cell surface expression. Eliminating the charge at Glu(206) (E206Q) resulted in loss of organic cation transport activity, whereas conserving the negative charge (E206D) restored transporter function. Interestingly, mutant E206Q, which possesses the equivalent residue in ENT1, gained uridine transport activity. Thr(220), another residue in TM5, also showed an effect on PMAT activity. Helical wheel analysis of TM5 revealed a distinct amphipathic pattern with Glu(206) and Thr(220) clustered in the center of the hydrophilic face. In summary, our results suggest that Glu(206) functions as a critical charge sensor for cationic substrates and TM5 forms part of the substrate permeation pathway in PMAT.     

Studies of nucleoside transporters using novel autofluorescent nucleoside probes

To better understand nucleoside transport processes and intracellular fates of nucleosides, we have developed a pair of fluorescent nucleoside analogues, FuPmR and dFuPmR, that differ only in the sugar moiety (ribofuranosyl versus 2'-deoxy, respectively), for real-time analysis of nucleoside transport into living cells by confocal microscopy. The binding and transportability of the two compounds were assessed for five recombinant human nucleoside transporters (hENT1/2, hCNT1/2/3) produced in Saccharomyces cerevisiae and/or oocytes of Xenopus laevis. The ribosyl derivative (FuPmR) was used to demonstrate proof of principle in live cell imaging studies in 11 cultured human cancer cell lines with different hENT1 activities. The autofluorescence emitted from FuPmR enabled direct visualization of its movement from the extracellular medium into the intracellular compartment of live cells, and this process was blocked by inhibitors of hENT1 (nitrobenzylmercaptopurine ribonucleoside, dipyridamole, and dilazep). Quantitative analysis of fluorescence signals revealed two stages of FuPmR uptake: a fast first stage that represented the initial uptake rate (i.e., transport rate) followed by a slow long-lasting second stage. The accumulation of FuPmR and/or its metabolites in nuclei and mitochondria was also visualized by live cell imaging. Measurements of fluorescence intensity increases in nuclei and mitochondria revealed rate-limited processes of permeant translocation across intracellular membranes, demonstrating for the first time the intracellular distribution of nucleosides and/or nucleoside metabolites in living cells. The use of autofluorescent nucleosides in time-lapse confocal microscopy is a novel strategy to quantitatively study membrane transport of nucleosides and their metabolites that will provide new knowledge of nucleoside biology.     

Analysis of transmembrane domain 2 of rat serotonin transporter by cysteine scanning mutagenesis

The second transmembrane domain (TM2) of neurotransmitter transporters has been invoked to control oligomerization and surface expression. This transmembrane domain lies between TM1 and TM3, which have both been proposed to contain residues that contribute to the substrate binding site. Rat serotonin transporter (SERT) TM2 was investigated by cysteine scanning mutagenesis. Six mutants in which cysteine replaced an endogenous TM2 residue had low transport activity, and two were inactive. Most of the reduction in transport activity was due to decreased surface expression. In contrast, M124C and G128C showed increased activity and surface expression. Random mutagenesis at positions 124 and 128 revealed that hydrophobic residues at these positions also increased activity. When modeled as an alpha-helix, positions where mutation to cysteine strongly affects expression levels clustered on the face of TM2 surrounding the leucine heptad repeat conserved within this transporter family. 2-(Aminoethyl)-methanethiosulfonate hydrobromide (MTSEA)-biotin labeled A116C and Y136C but not F117C, M135C, or Y134C, suggesting that these residues may delimit the transmembrane domain. None of the cysteine substitution mutants from 117 through 135 were sensitive to [2-(trimethylammonium)ethyl]methanethiosulfonate bromide (MTSET) or MTSEA. However, treatment with MTSEA increased 5-hydroxytryptamine transport by A116C. Activation of A116C by MTSEA was observed only in mutants containing Cys to Ile mutation at position 357, suggesting that modification of Cys-116 activated transport by compensating for a disruption in transport in response to Cys-357 replacement. The reactivity of A116C toward MTSEA was substantially increased in the presence of substrates but not inhibitors. This increase required Na+ and Cl-, and was likely to result from conformational changes during the transport process.     

Kinetic and pharmacological properties of cloned human equilibrative nucleoside transporters, ENT1 and ENT2, stably expressed in nucleoside transporter-deficient PK15 cells. Ent2 exhibits a low affinity for guanosine and cytidine but a high affinity for inosine

We stably transfected the cloned human equilibrative nucleoside transporters 1 and 2 (hENT1 and hENT2) into nucleoside transporter-deficient PK15NTD cells. Although hENT1 and hENT2 are predicted to be 50-kDa proteins, hENT1 runs as 40 kDa and hENT2 migrates as 50 and 47 kDa on SDS-polyacrylamide gel electrophoresis. Peptide N-glycosidase F and endoglycosidase H deglycosylate hENT1 to 37 kDa and hENT2 to 45 kDa. With hENT1 being more sensitive, there is a 7000-fold and 71-fold difference in sensitivity to nitrobenzylthioinosine (NBMPR) (IC(50), 0.4 +/- 0.1 nM versus 2.8 +/- 0.3 microM) and dipyridamole (IC(50), 5.0 +/- 0.9 nM versus 356 +/- 13 nM), respectively. [(3)H]NBMPR binds to ENT1 cells with a high affinity K(d) of 0.377 +/- 0.098 nM, and each ENT1 cell has 34,000 transporters with a turnover number of 46 molecules/s for uridine. Although both transporters are broadly selective, hENT2 is a generally low affinity nucleoside transporter with 2.6-, 2.8-, 7. 7-, and 19.3-fold lower affinity than hENT1 for thymidine, adenosine, cytidine, and guanosine, respectively. In contrast, the affinity of hENT2 for inosine is 4-fold higher than hENT1. The nucleobase hypoxanthine inhibits [(3)H]uridine uptake by hENT2 but has minimal effect on hENT1. Taken together, these results suggest that hENT2 might be important in transporting adenosine and its metabolites (inosine and hypoxanthine) in tissues such as skeletal muscle where ENT2 is predominantly expressed.     

Equilibrative nucleoside transporters: mapping regions of interaction for the substrate analogue nitrobenzylthioinosine (NBMPR) using rat chimeric proteins.

The rat equilibrative nucleoside transporters rENT1 and rENT2 belong to a family of integral membrane proteins with 11 potential transmembrane segments (TMs) and are distinguished functionally by differences in sensitivity to inhibition by nitrobenzylthioinosine (NBMPR). Structurally, the proteins have a large glycosylated extracellular loop between TMs 1 and 2 and a large cytoplasmic loop between TMs 6 and 7. In the present study, we have generated chimeras between NBMPR-sensitive rENT1 and NBMPR-insensitive rENT2, using splice sites at rENT1 residues 99 (end of TM 2), 171 (between TMs 4 and 5), and 231 (end of TM 6) to identify structural domains of rENT1 responsible for transport inhibition by NBMPR. Transplanting the amino-terminal half of rENT2 into rENT1 rendered rENT1 NBMPR-insensitive. Domain swaps within the amino-terminal halves of rENT1 and rENT2 identified two contiguous regions, TMs 3-4 (rENT1 residues 100-171) and TMs 5-6 (rENT1 residues 172-231), as the major sites of NBMPR interaction. Since NBMPR is a nucleoside analogue and functions as a competitive inhibitor of zero-trans nucleoside influx, TMs 3-6 are likely to form parts of the substrate translocation channel.     

Uridine Recognition Motifs of Human Equilibrative Nucleoside Transporters 1 and 2 Produced in Saccharomyces cerevisiae

The sugar moiety of nucleosides has been shown to play a major role in permeant‐transporter interaction with human equilibrative nucleoside transporters 1 and 2 (hENT1 and hENT2). To better understand the structural requirements for interactions with hENT1 and hENT2, a series of uridine analogs with sugar modifications were subjected to an assay that tested their abilities to inhibit [³H]uridine transport mediated by recombinant hENT1 and hENT2 produced in Saccharomyces cerevisiae. hENT1 displayed higher affinity for uridine than hENT2. Both transporters barely tolerated modifications or inversion of configuration at C(3′). The C(2′)‐OH at uridine was a structural determinant for uridine‐hENT1, but not for uridine‐hENT2, interactions. Both transporters were sensitive to modifications at C(5′) and hENT2 displayed more tolerance to removal of C(5′)‐OH than hENT1; addition of an O‐methyl group at C(5′) greatly reduced interaction with either hENT1 or hENT2. The changes in binding energies between transporter proteins and the different uridine analogs suggested that hENT1 formed strong interactions with C(3′)‐OH and moderate interactions with C(2′)‐OH and C(5′)‐OH of uridine, whereas hENT2 formed strong interactions with C(3′)‐OH, weak interactions with C(5′)‐OH, and no interaction with C(2′)‐OH.     

Uridine recognition motifs of human equilibrative nucleoside transporters 1 and 2 produced in Saccharomyces cerevisiae

The sugar moiety of nucleosides has been shown to play a major role in permeant-transporter interaction with human equilibrative nucleoside transporters 1 and 2 (hENT1 and hENT2). To better understand the structural requirements for interactions with hENT1 and hENT2, a series of uridine analogs with sugar modifications were subjected to an assay that tested their abilities to inhibit [3H]uridine transport mediated by recombinant hENT1 and hENT2 produced in Saccharomyces cerevisiae. hENT1 displayed higher affinity for uridine than hENT2. Both transporters barely tolerated modifications or inversion of configuration at C(3'). The C(2')-OH at uridine was a structural determinant for uridine-hENT1, but not for uridine-hENT2, interactions. Both transporters were sensitive to modifications at C(5') and hENT2 displayed more tolerance to removal of C(5')-OH than hENT1; addition of an O-methyl group at C(5') greatly reduced interaction with either hENT1 or hENT2. The changes in binding energies between transporter proteins and the different uridine analogs suggested that hENT1 formed strong interactions with C(3')-OH and moderate interactions with C(2')-OH and C(5')-OH of uridine, whereas hENT2 formed strong interactions with C(3')-OH, weak interactions with C(5')-OH, and no interaction with C(2')-OH.     

Specific mutations in transmembrane helix 8 of human concentrative Na+/nucleoside cotransporter hCNT1 affect permeant selectivity and cation coupling

The Na+/nucleoside cotransporters hCNT1 (650 residues) and hCNT2 (658 residues) are 72% identical in amino acid sequence and contain 13 putative transmembrane helices (TMs). Both transport uridine and adenosine but are otherwise selective for pyrimidine (system cit) and purine (system cif) nucleosides, respectively. Previously, we used site-directed mutagenesis and functional expression in Xenopus oocytes to identify two pairs of adjacent residues in TMs 7 and 8 of hCNT1 (Ser319-Gln320 and Ser353-Leu354) that, when converted to the corresponding residues in hCNT2 (Gly-Met and Thr-Val, respectively), changed the permeant selectivity of the transporter from cit to cif. We now report an investigation of the effects of corresponding mutations in TM 8 alone and demonstrate unique S353T- and L354V-induced changes in nucleoside specificity and cation coupling, respectively. hCNT1 mutation S353T produced a profound decrease in cytidine transport efficiency (Vmax/Km ratio) and, in combination with L354V (S353T/L354V), resulted in a novel uridine-preferring transport phenotype. In addition, the L354V mutation markedly increased the apparent affinity of hCNT1 for Na+ and Li+. Both hCNT1 TM 8 residues exhibited uridine-protectable inhibition by p-chloromercuribenzene sulfonate when converted to Cys, suggesting that they occupy positions within or closely adjacent to a common cation/nucleoside translocation pore.     

Conserved residues F316 and G476 in the concentrative nucleoside transporter 1 (hCNT1) affect guanosine sensitivity and membrane expression, respectively

The functional significance of two highly conserved amino acid residues, F316 [putative transmembrane domain (TM)7] and G476 (putative TM11), in the concentrative nucleoside transporter hCNT1 (SLC28A1) was examined by performing site-directed mutagenesis. Conservative mutations at these positions (F316A, F316Y, G476A, and G476L) were generated and expressed in Madin-Darby canine kidney (MDCK) cells as fusion polypeptides with green fluorescent protein (GFP). Unlike wild-type hCNT1, G476A-GFP and G476L-GFP were not expressed in the plasma membrane in undifferentiated or differentiated MDCK cells and had no functional activity. Like wild-type hCNT1, F316A-GFP and F316Y-GFP were expressed in the plasma membrane of undifferentiated MDCK cells and in the apical membrane of differentiated MDCK cells. Remarkably, transport of [³H]uridine by F316Y-GFP or F316A-GFP was highly sensitive to inhibition by guanosine. Furthermore, genotyping of exon 11 of hCNT1 (TM7) in a panel of 260 anonymous human DNA samples revealed a novel F316H variant (TT>CA; 1/260). When expressed in MDCK cells, [³H]uridine transport by F316H was also found to be sensitive to inhibition by guanosine (IC₅₀ = 148 µM). The effect of the F316H mutation resembles the N4 type nucleoside transporter phenotype previously reported to be present in human kidneys. We suggest that the N4 transport system is a naturally occurring variant of hCNT1, perhaps at the F316 position. Collectively, our data show that G476 is important for correct membrane targeting, folding, and/or intracellular processing of hCNT1. In addition, we have discovered that hCNT1 displays natural variation at position F316 and that the variant F316H confers on the transporter an unusual sensitivity to inhibition by guanosine. localization; inhibition; polymorphism     

Identification of basic residues involved in drug export function of human multidrug resistance-associated protein 2

Multidrurg resistance-associated protein 2 (MRP2)/canalicular multispecific organic anion transporter (cMOAT) is involved in the ATP-dependent export of organic anions across the bile canalicular membrane. To identify functional amino acid residues that play essential roles in the substrate transport, each of 13 basic residues around transmembrane regions (TMs) 6-17 were replaced with alanine. Wild type and mutant proteins were expressed in COS-7 cells, and the transport activity was measured as the excretion of glutathione-methylfluorescein. Four mutants, K324A (TM6), K483A (TM9), R1210A (TM16), and R1257A (TM17), showed decreased transport activity, and another mutant, K578A (TM11), showed decreased protein expression. These five mutants were normally delivered to the cell surface similar to the other fully active mutants and wild type MRP2. The importance of TM6, TM16, and TM17 in the transport function of MRP2 is consistent with the previous observation indicating the importance of the corresponding TM1, TM11, and TM12 on P-glycoprotein (Loo, T. W., and Clarke, D. M. (1999) J. Biol. Chem. 274, 35388-35392). Another observation that MRP2 inhibitor, cyclosporine A, failed to inhibit R1230A specifically, indicated the existence of its binding site within TM16.     

Coupling of CFTR-mediated anion secretion to nucleoside transporters and adenosine homeostasis in calu-3 cells

The purpose of this study was to characterize the role of adenosine-dependent regulation of anion secretion in Calu-3 cells. RT-PCR studies showed that Calu-3 cells expressed mRNA for A2A and A2B but not A1 or A3 receptors, and for hENT1, hENT2 and hCNT3 but not hCNT1 or hCNT2 nucleoside transporters. Short-circuit current measurements indicated that A2B receptors were present in both apical and basolateral membranes, whereas A2A receptors were detected only in basolateral membranes. Uptake studies demonstrated that the majority of adenosine transport was mediated by hENT1, which was localized to both apical and basolateral membranes, with a smaller hENT2-mediated component in basolateral membranes. Whole-cell current measurements showed that application of extracellular nitrobenzylmercaptopurine ribonucleoside (NBMPR), a selective inhibitor of hENT1-mediated transport, had similar effects on whole-cell currents as the application of exogenous adenosine. Inhibitors of adenosine kinase and 5'-nucleotidase increased and decreased, respectively, whole-cell currents, whereas inhibition of adenosine deaminase had no effect. Single-channel studies showed that NBMPR and adenosine kinase inhibitors activated CFTR Cl- channels. These results suggested that the equilibrative nucleoside transporters (hENT1, hENT2) together with adenosine kinase and 5'-nucleotidase play a crucial role in the regulation of CFTR through an adenosine-dependent pathway in human airway epithelia.