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  • Interaction of a series of draflazine analogues with equilibrative nucleoside transporters: species differences and transporter subtype selectivity.

Interaction of a series of draflazine analogues with equilibrative nucleoside transporters: species differences and transporter subtype selectivity.

Naunyn-Schmiedeberg's archives of pharmacology (2000-04-14)
J R Hammond
ABSTRACT

The equilibrative nucleoside transporters of mammalian cells play an important role in the regulation of extracellular adenosine concentrations, and inhibition of these transporters potentiates the biological effects of adenosine. Two subtypes of equilibrative transporters have been defined by their differential sensitivities to inhibition by nitrobenzylthioinosine (NBMPR; es/ENT1, sensitive; ei/ENT2, insensitive). In addition, significant species differences have been noted in es/ENT1 transporter affinity for a subset of inhibitors including draflazine and dipyridamole. Draflazine and a series of 15 chemically related compounds were compared for their abilities to: (a) inhibit the binding of [3H]NBMPR to the es/ENT1 transporter in mouse Ehrlich cell and human erythrocyte membranes, and (b) inhibit the es/ENT1 and ei/ENT2 transporter-mediated uptake of [3H]uridine in Ehrlich cells. Compounds within this series represented over a 1000-fold range of affinities for the es/ENT1 and ei/ENT2 transporters with subtype selectivities (ENT1/ENT2) ranging from 370 for R70527 to 0.17 for soluflazine. Five other analogues were identified, in addition to soluflazine, that had significantly higher affinity for the ei/ENT2 transporter compared with es/ENT1. Structure activity analyses of these data identified the requirement of a hydrophobic group connected to a 2-aminocarbonyl piperazine by a 5-carbon chain for high-affinity interactions with es/ENT1. This hydrophobic moiety was not as important for ei/ENT2 affinity and, in contrast to es/ENT1, a shorter alkyl chain enhanced binding to ei/ENT2. These draflazine analogues also varied in their differential affinities for mouse vs. human es/ENT1 transporters, and the degree of species discrimination was strongly dependent on the position of the aminocarbonyl group on the piperazine ring. This information, combined with structural data derived from molecular studies with ENT1 and ENT2 recombinant proteins, should guide further development of subtype-selective inhibitors of the equilibrative nucleoside transporters.