Mazzon Cristina, Rampazzo Chiara, Scaini Maria Chiara, Gallinaro Lisa, Karlsson Anna, Meier Chris, Balzarini Jan, Reichard Peter, Bianchi Vera
Department of Biology, University of Padova, 35131 Padova, Italy.
Biochem Pharmacol. 2003 Aug 1;66(3):471-9. doi: 10.1016/s0006-2952(03)00290-9.
Nucleoside analogs act as prodrugs that must be converted to 5'-phosphates by intracellular kinases to become active in the treatment of viral and oncological diseases. Activation may be reversed by dephosphorylation if the 5'-phosphates are substrates for 5'-nucleotidases. Dephosphorylation by cytosolic enzymes decreases the efficacy of the analogs, whereas dephosphorylation by mitochondrial enzymes may decrease mitochondrial toxicity. Both effects may influence the outcome of therapy. We investigated the dephosphorylation of the 5'-phosphates of commonly used nucleoside analogs by two cytosolic (cN-II and dNT-1) and one mitochondrial (dNT-2) nucleotidase. Most uracil/thymine nucleotide analogs were dephosphorylated by all three human enzymes but cytosine-containing nucleotide analogs were inactive. Only cN-II showed some activity with the monophosphates of the two purine analogs 2-chloro-2'-deoxyadenosine and 9-beta-D-arabinosylguanine. We conclude that overproduction of any of the three 5'-nucleotidases cannot explain development of resistance against cytosine analogs but that overproduction of cN-II could lead to resistance against purine analogs. Of the tested analogs, only (E)-5-(2-bromovinyl)-2'-deoxyuridine was preferentially dephosphorylated by mitochondrial dNT-2. We propose that in future developments of analogs this aspect be considered in order to reduce mitochondrial toxicity. We tested inhibition of dNT-1 and dNT-2 by a large variety of synthetic metabolically stable nucleoside phosphonate analogs and found one (PMcP-U) that inhibited dNT-1 and dNT-2 competitively and a second (DPB-T) that inhibited dNT-2 by mixed inhibition. Both inhibitors are useful for specific 5'-nucleotidase assays and structural studies and may open up possibilities for therapy.
核苷类似物作为前体药物,必须通过细胞内激酶转化为5'-磷酸酯才能在治疗病毒和肿瘤疾病中发挥作用。如果5'-磷酸酯是5'-核苷酸酶的底物,去磷酸化可使激活作用逆转。胞质酶的去磷酸化会降低类似物的疗效,而线粒体酶的去磷酸化可能会降低线粒体毒性。这两种效应都可能影响治疗结果。我们研究了两种胞质(cN-II和dNT-1)和一种线粒体(dNT-2)核苷酸酶对常用核苷类似物5'-磷酸酯的去磷酸化作用。大多数尿嘧啶/胸腺嘧啶核苷酸类似物都能被这三种人类酶去磷酸化,但含胞嘧啶的核苷酸类似物无活性。只有cN-II对两种嘌呤类似物2-氯-2'-脱氧腺苷和9-β-D-阿拉伯糖基鸟嘌呤的单磷酸酯表现出一定活性。我们得出结论,三种5'-核苷酸酶中任何一种的过量产生都不能解释对胞嘧啶类似物耐药性的产生,但cN-II的过量产生可能导致对嘌呤类似物的耐药性。在测试的类似物中,只有(E)-5-(2-溴乙烯基)-2'-脱氧尿苷优先被线粒体dNT-2去磷酸化。我们建议在类似物的未来开发中考虑这一方面,以降低线粒体毒性。我们测试了多种合成代谢稳定的核苷膦酸类似物对dNT-1和dNT-2的抑制作用,发现一种(PMcP-U)竞争性抑制dNT-1和dNT-2,另一种(DPB-T)通过混合抑制作用抑制dNT-2。这两种抑制剂都可用于特定的5'-核苷酸酶测定和结构研究,并可能为治疗开辟可能性。
