An Advanced In Silico Modelling of the Interaction between FSCPX, an Irreversible A1 Adenosine Receptor Antagonist, and NBTI, a Nucleoside Transport Inhibitor, in the Guinea Pig Atrium.

In earlier studies, we generated concentration-response (E/c) curves with CPA (N6-cyclopentyladenosine; a selective A1 adenosine receptor agonist) or adenosine, in the presence or absence of S-(2-hydroxy-5-nitrobenzyl)-6-thioinosine (NBTI, a selective nucleoside transport inhibitor), and with or without a pretreatment with 8-cyclopentyl-N3-[3-(4-(fluorosulfonyl)-benzoyloxy)propyl]-N1-propylxanthine (FSCPX, a chemical known as a selective, irreversible A1 adenosine receptor antagonist), in isolated, paced guinea pig left atria. Meanwhile, we observed a paradoxical phenomenon, i.e. the co-treatment with FSCPX and NBTI appeared to enhance the direct negative inotropic response to adenosine. In the present in silico study, we aimed to reproduce eight of these E/c curves. Four models (and two additional variants of the last model) were constructed, each one representing a set of assumptions, in order to find the model exhibiting the best fit to the ex vivo data, and to gain insight into the paradoxical phenomenon in question. We have obtained in silico evidence for an interference between effects of FSCPX and NBTI upon our ex vivo experimental setting. Regarding the mechanism of this interference, in silico evidence has been gained for the assumption that FSCPX inhibits the effect of NBTI on the level of endogenous (but not exogenous) adenosine. As an explanation, it may be hypothesized that FSCPX inhibits an enzyme participating in the interstitial adenosine formation. In addition, our results suggest that NBTI does not stop the inward adenosine flux in the guinea pig atrium completely.

Structure-activity relationships in fungal nucleobases transporters as dissected by the inhibitory effects of novel purine analogues.

We have previously rationally designed, synthesized and tested a number of 3-deazapurine analogues, which inhibit the ubiquitous fungal nucleobase transporter FcyB, through binding in its major substrate binding site, by specifically interacting with Asn163. Here, in an effort to further understand the molecular details of structure-activity relationships in all three major nucleobase transporters of fungi, we extend this study by designing, based on our previous experience, synthesizing and testing further 3-deazapurine analogues. We thus identify seven new compounds with relatively high affinity (19-106 µΜ) for the FcyB binding site. Importantly, four of these compounds can also efficiently inhibit AzgA, a structurally and evolutionary distinct, but functionally similar, purine transporter. Contrastingly, none of the new compounds tested had any effect on the transport activity of the uric acid-xanthine transporter UapA, albeit this being a structural homologue of AzgA. Besides the apparent importance for understanding how nucleobase transporter specificity is determined at the molecular level, our work might constitute a critical step in the design of novel purine-related antifungals.

Design and synthesis of purine analogues as highly specific ligands for FcyB, a ubiquitous fungal nucleobase transporter.

In the course of our study on fungal purine transporters, a number of new 3-deazapurine analogues have been rationally designed, based on the interaction of purine substrates with the Aspergillus nidulans FcyB carrier, and synthesized following an effective synthetic procedure. Certain derivatives have been found to specifically inhibit FcyB-mediated [3H]-adenine uptake. Molecular simulations have been performed, suggesting that all active compounds interact with FcyB through the formation of hydrogen bonds with Asn163, while the insertion of hydrophobic fragments at position 9 and N6 of 3-deazaadenine enhanced the inhibition.

Inhibition of sodium-independent and sodium-dependent nucleobase transport activities by tyrosine kinase inhibitors.

PURPOSE: Effects of tyrosine kinase inhibitors (TKIs) on equilibrative nucleobase transport (ENBT) and sodium-dependent nucleobase transport (SNBT) activities were investigated in normal human renal proximal tubule epithelial cells (hRPTECs) and in pig kidney cell line (LLC-PK1). METHODS: Uptake assays were performed by assessing accumulation of radiolabeled nucleobases over time into hRPTECs or LLC-PK1 cell lines which express ENBT and SNBT activities, respectively. Dose-response curves for inhibition of 1 µM [(3)H]adenine or 1 µM [(3)H]hypoxanthine were examined in hRPTECs and in LLC-PK1 cells with varying TKI concentrations (0-100 µM) to calculate the IC50 values (mean ± S.E) for inhibition. RESULTS: Gefitinib inhibited ENBT activity with an IC50 value of 0.7 µM, thus indicating strong interactions of ENBT with gefitinib in hRPTECs. Erlotinib > sorafenib > imatinib > sunitinib inhibited ENBT with IC50 values of 15, 40, 60, 78 µM, respectively, whereas dasatinib, lapatinib, and vandetanib were not inhibitory at concentrations >100 µM. Similar studies in LLC-PK1 cells which exhibit SNBT activity showed that vandetanib was the most potent inhibitor followed by sorafenib > erlotinib > gefitinib > sunitinib > imatinib with IC50 values of 14, 25, 28, 40, 47, 94 µM, respectively, whereas dasatinib and lapatinib were not inhibitory at concentrations >100 µM. CONCLUSIONS: These results suggest for the first time inhibition of both ENBT and SNBT transport activities by TKIs. These results suggest that it is important to consider potential effects on combination regimens using TKIs with nucleobase drugs such as 5-FU in cancer treatment.

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.