Mabel W. L. Ritzel

Distribution and Functional Characterization of Equilibrative Nucleoside Transporter-4, a Novel Cardiac Adenosine Transporter Activated at Acidic pH

Adenosine plays multiple roles in the efficient functioning of the heart by regulating coronary blood flow, cardiac pacemaking, and contractility. Previous studies have implicated the equilibrative nucleoside transporter family member equilibrative nucleoside transporter-1 (ENT1) in the regulation of cardiac adenosine levels. We report here that a second member of this family, ENT4, is also abundant in the heart, in particular in the plasma membranes of ventricular myocytes and vascular endothelial cells but, unlike ENT1, is virtually absent from the sinoatrial and atrioventricular nodes. Originally described as a monoamine/organic cation transporter, we found that both human and mouse ENT4 exhibited a novel, pH-dependent adenosine transport activity optimal at acidic pH (apparent Km values 0.78 and 0.13 mmol/L, respectively, at pH 5.5) and absent at pH 7.4. In contrast, serotonin transport by ENT4 was relatively insensitive to pH. ENT4-mediated nucleoside transport was adenosine selective, sodium independent and only weakly inhibited by the classical inhibitors of equilibrative nucleoside transport, dipyridamole, dilazep, and nitrobenzylthioinosine. We hypothesize that ENT4, in addition to playing roles in cardiac serotonin transport, contributes to the regulation of extracellular adenosine concentrations, in particular under the acidotic conditions associated with ischemia.

Nucleoside Transporters of Mammalian Cells

In this review, we have summarized recent advances in our understanding of the biology of nucleoside transport arising from new insights provided by the isolation and functional expression of cDNAs encoding the major nucleoside transporters of mammalian cells. Nucleoside transporters are required for permeation of nucleosides across biological membranes and are present in the plasma membranes of most cell types. There is growing evidence that functional nucleoside transporters are required for translocation of nucleosides between intracellular compartments and thus are also present in organellar membranes. Functional studies during the 1980s established that nucleoside transport in mammalian cells occurs by two mechanistically distinct processes, facilitated diffusion and Na(+)-nucleoside cotransport. The determination of the primary amino acid sequences of the equilibrative and concentrative transporters of human and rat cells has provided a structural basis for the functional differences among the different transporter subtypes. Although nucleoside transporter proteins were first purified from human erythrocytes a decade ago, the low abundance of nucleoside transporter proteins in membranes of mammalian cells has hindered analysis of relationships between transporter structure and function. The molecular cloning of cDNAs encoding nucleoside transporters and the development of heterologous expression systems for production of recombinant nucleoside transporters, when combined with recombinant DNA technologies, provide powerful tools for characterization of functional domains within transporter proteins that are involved in nucleoside recognition and translocation. As relationships between molecular structure and function are determined, it should be possible to develop new approaches for optimizing the transportability of nucleoside drugs into diseased tissues, for development of new transport inhibitors, including reagents that are targeted to the concentrative transporters, and, eventually, for manipulation of transporter function through an understanding of the regulation of transport activity.

Recent molecular advances in studies of the concentrative Na+-dependent nucleoside transporter (CNT) family: identification and characterization of novel human and mouse proteins (hCNT3 and mCNT3) broadly selective for purine and pyrimidine nucleosides (system cib)

The human concentrative (Na+-linked) plasma membrane transport proteins hCNT1 and hCNT2, found primarily in specialized epithelia, are selective for pyrimidine nucleosides (system cit) and purine nucleosides (system cif), respectively. Both have orthologs in other mammalian species and belong to a gene family (CNT) that also includes members in lower vertebrates, insects, nematodes, pathogenic yeast and bacteria. The CNT transporter family also includes a newly identified human and mouse CNT3 transporter isoform. This paper reviews the studies of CNT transport proteins that led to the identification of hCNT3 and mCNT3, and gives an overview of the structural and functional properties of these latest CNT family members. hCNT3 and mCNT3 have primary structures that place them in a CNT subfamily separate from CNT1/2, transport a wide range of physiological pyrimidine and purine nucleosides and antineoplastic and antiviral nucleoside drugs (system cib), and exhibit a Na+:uridine coupling ratio of at least 2:1 (cf 1:1 for hCNT1/2). Cells and tissues containing hCNT3 transcripts include mammary gland, differentiated HL-60 cells, pancreas, bone marrow, trachea, liver, prostrate and regions of intestine, brain and heart. In HL-60 cells, hCNT3 is transcriptionally regulated by phorbol myristate (PMA). The hCNT3 gene, which contains an upstream PMA response element, mapped to 9q22.2 (cf chromosome 15 for hCNT1 and hCNT2).The human concentrative (Na+-linked) plasma membrane transport proteins hCNT1 and hCNT2, found primarily in specialized epithelia, are selective for pyrimidine nucleosides (system cit) and purine nucleosides (system cif), respectively. Both have orthologs in other mammalian species and belong to a gene family (CNT) that also includes members in lower vertebrates, insects, nematodes, pathogenic yeast and bacteria. The CNT transporter family also includes a newly identified human and mouse CNT3 transporter isoform. This paper reviews the studies of CNT transport proteins that led to the identification of hCNT3 and mCNT3, and gives an overview of the structural and functional properties of these latest CNT family members. hCNT3 and mCNT3 have primary structures that place them in a CNT subfamily separate from CNT1/2, transport a wide range of physiological pyrimidine and purine nucleosides and antineoplastic and antiviral nucleoside drugs (system cib), and exhibit a Na+:uridine coupling ratio of at least 2:1 (cf 1:1 for hCNT1/2). Cells and tissues containing hCNT3 transcripts include mammary gland, differentiated HL-60 cells, pancreas, bone marrow, trachea, liver, prostrate and regions of intestine, brain and heart. In HL-60 cells, hCNT3 is transcriptionally regulated by phorbol myristate (PMA). The hCNT3 gene, which contains an upstream PMA response element, mapped to 9q22.2 (cf chromosome 15 for hCNT1 and hCNT2).

Identification and functional characterization of variants in human concentrative nucleoside transporter 3, hCNT3 (SLC28A3), arising from single nucleotide polymorphisms in coding regions of the hCNT3 gene.

Introduction Human concentrative nucleoside transporter 3, hCNT3 (SLC28A3), which mediates transport of purine and pyrimidine nucleosides and a variety of antiviral and anticancer nucleoside drugs, was investigated to determine if there are single nucleotide polymorphisms in the coding regions of the hCNT3 gene. Methods and results Ninety-six DNA samples from Caucasians (Coriell Panel) were sequenced and sixteen variants in exons and flanking intronic regions were identified, of which five were coding variants; three of these were non-synonymous (S5N, L131F, Y513F) and were further investigated for functional alterations of the resulting recombinant proteins in Saccharomyces cerevisiae and Xenopus laevis oocytes. In yeast, immunostaining and fluorescence quantitation of the reference (wild-type) and variant CNT3 proteins showed similar levels of expression. Kinetic studies were undertaken in yeast with a high through-put semi-automated assay process; reference hCNT3 exhibited Km values of 1.7±0.3, 3.6±1.3, 2.2±0.7, and 2.1±0.6 μM and Vmax values of 1402±286, 1310±113, 1020±44, and 1740±114 pmol/mg/min, respectively, for uridine, cytidine, adenosine and inosine. Similar Km and Vmax values were obtained for the three variant proteins assayed in yeast under identical conditions. All of the characterized hCNT3 variants produced in oocytes retained sodium and proton dependence of uridine transport based on measurements of radioisotope flux and two-electrode voltage-clamp studies. Conclusion These results suggested a high degree of conservation of function for hCNT3 in the Caucasian population.

Cysteine-accessibility analysis of transmembrane domains 11-13 of human concentrative nucleoside transporter 3

hCNT3 (human concentrative nucleoside transporter 3) is a nucleoside-sodium symporter that transports a broad range of naturally occurring purine and pyrimidine nucleosides as well as anticancer nucleoside drugs. To understand its uridine binding and translocation mechanisms, a cysteine-less version of hCNT3 was constructed and used for cysteine-accessibility and permeant-protection assays. Cysteine-less hCNT3, with 14 endogenous cysteine residues changed to serine, displayed wild-type properties in a yeast expression system, indicating that endogenous cysteine residues are not essential for hCNT3-mediated nucleoside transport. A series of cysteine-substitution mutants spanning predicted TMs (transmembrane domains) 11-13 was constructed and tested for accessibility to thiol-specific reagents. Mutants M496C, G498C, F563C, A594C, G598C and A606C had no detectable transport activity, indicating that a cysteine substitution at each of these positions was not tolerated. Two functional mutants in putative TM 11 (L480C and S487C) and four in putative TM 12 (N565C, T557C, G567C and I571C) were partially inhibited by MTS (methanethiosulphonate) reagent and high concentrations of uridine protected against inhibition, indicating that TMs 11 and 12 may form part of the nucleoside translocation pathway. The lack of accessibility of MTS reagents to TM 13 mutants suggests that TM 13 is not exposed to the nucleoside translocation pathway. Furthermore, G567C, N565C and I571C mutants were only sensitive to MTSEA (MTS-ethylammonium), a membranepermeant thiol reagent, indicating that these residues may be accessible from the cytoplasmic side of the membrane, providing evidence in support of the predicted orientation of TM 12 in the current putative topology model of hCNT3.

Adenosine transport: Recent advances in the molecular biology of nucleoside transporter proteins

Adenosine is a hydrophilic molecule that requires specialized transport proteins for permeation of cell membranes. Functional studies have identified two types of nucleoside transport processes: equilibrative bidirectional processes driven by chemical gradients and inwardly directed concentrative processes driven by the sodium electrochemical gradient. The equilibrative nucleoside transport processes (es, ei) are widely distributed among various cell types, whereas the concentrative nucleoside transport processes (cit, cif, cib, csg, cs) are present primarily in specialized epithelia. Using molecular cloning techniques and functional expression of cDNAs in oocytes of Xenopus laevis, we have isolated and characterized cDNAs encoding integral membrane proteins of the four major nucleoside transport processes of rat and human cells (es, ei, cit, cif). The equilibrative and concentrative nucleoside transport processes are mediated by members of two previously unrecognized groups of integral membrane proteins, which we have designated the Equilibrative Nucleoside Transporter (ENT) and the Concentrative Nucleoside Transporter (CNT) protein families. This review summarizes the current state of knowledge of the molecular biology of the ENT and CNT protein families, focusing on the role of these proteins (r/hENT1, r/hENT2, r/hCNT1, r/hCNT2) in the transport of adenosine. Drug Dev. Res. 45:277–287, 1998.