9-(2′-Deoxy-2′-Fluoro-β-d-Arabinofuranosyl) Adenine Is a Potent Antitrypanosomal Adenosine Analogue That Circumvents Transport-Related Drug Resistance

ABSTRACT Current chemotherapy against African sleeping sickness, a disease caused by the protozoan parasite Trypanosoma brucei, is limited by toxicity, inefficacy, and drug resistance. Nucleoside analogues have been successfully used to cure T. brucei-infected mice, but they have the limitation of mainly being taken up by the P2 nucleoside transporter, which, when mutated, is a common cause of multidrug resistance in T. brucei. We report here that adenine arabinoside (Ara-A) and the newly tested drug 9-(2′-deoxy-2′-fluoro-β-d-arabinofuranosyl) adenine (FANA-A) are instead taken up by the P1 nucleoside transporter, which is not associated with drug resistance. Like Ara-A, FANA-A was found to be resistant to cleavage by methylthioadenosine phosphorylase, an enzyme that protects T. brucei against the antitrypanosomal effects of deoxyadenosine. Another important factor behind the selectivity of nucleoside analogues is how well they are phosphorylated within the cell. We found that the T. brucei adenosine kinase had a higher catalytic efficiency with FANA-A than the mammalian enzyme, and T. brucei cells treated with FANA-A accumulated high levels of FANA-A triphosphate, which even surpassed the level of ATP and led to cell cycle arrest, inhibition of DNA synthesis, and the accumulation of DNA breaks. FANA-A inhibited nucleic acid biosynthesis and parasite proliferation with 50% effective concentrations (EC50s) in the low nanomolar range, whereas mammalian cell proliferation was inhibited in the micromolar range. Both Ara-A and FANA-A, in combination with deoxycoformycin, cured T. brucei-infected mice, but FANA-A did so at a dose 100 times lower than that of Ara-A.

Biosynthesis of Adenine Arabinoside by Whole Cells of Enterobacter aerogenes HXY2222

Adenine Arabinoside were prepared from Ara-U and adenine using whole cells of Enterobacter aerogenes HXY2222. After incubated for 16h, 10% wet cells was added to the reaction mixture, containing 10mM AraU and adenine. The transarabinosylation reaction was carried out at 60°C, in pH 7.5 phosphate buffer, for 30h, and the yield was achieved 83%, based on the molar ratio of both substrates. When the reaction was carried out with 30mM AraU and adenine, the yield of AraA droped significantly due to the low solubility of adeine. 20%~25% (v/v) DMSO were added into the reaction mixture, and a yield of 77% was achieved.

Specificity of human and rat orthologs of the concentrative nucleoside transporter, SPNT

To understand the roles that nucleoside transporters play in the in vivo distribution of clinically important nucleoside analogs, the substrate specificity of each transporter isoform should be determined. In the present work, we studied the substrate specificities of the human and rat orthologs of the Na+-dependent purine-selective nucleoside transporter (SPNT; concentrative nucleoside transporter 2), for nucleosides, nucleobases, and base- and ribose-modified nucleoside analogs. The two-electrode voltage-clamp technique in Xenopus laevisoocytes expressing these transporters was used. Purine nucleosides and uridine induced currents in oocytes expressing rat SPNT (rSPNT) or human SPNT1 (hSPNT1). The rank order of magnitude of nucleoside-induced currents was guanosine > uridine > adenosine > inosine and guanosine > uridine > inosine > adenosine for rSPNT- and hSPNT1-expressing oocytes, respectively. Uridine analogs (modified at the 5-position of the base) induced little or no current, suggesting that these compounds are only poorly transported by either transporter. Cladribine induced currents in oocytes expressing rSPNT ( K 0.5 = 57 ± 12 μM) but not hSPNT1. The ribose-modified nucleoside analogs, adenine arabinoside, and 2′,3′-dideoxyadenosine induced currents in rSPNT-expressing, but not in hSPNT1-expressing, oocytes. These data suggest that there are notable species differences in the specificity of SPNT for synthetic nucleoside analogs.