Jonathan P. Dolan, Tessa Keenan, Aisling Ní Cheallaigh, Martin A. Fascione and Gavin J. Miller
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引用次数: 0
摘要
核苷类似物治疗在药物发现中作为抗病毒和抗肿瘤药物具有被证实的能力。然而,它们的功效可能受到细胞摄取不良、脱靶毒性和低生物利用度的限制。药物制剂/天然产物的糖基化是一种战略性的简单方法来调节药理学特征。在这里,我们探索核苷类似物的生物催化糖基化。研究了来自Streptomyces sp. AVP053U2的核苷特异性3'- o -糖基转移酶AvpGT的活性,并对天然和临床相关的嘌呤和嘧啶核苷类似物进行了研究。AvpGT显示出广泛的底物混杂性,通过HILIC-MS观察到21种核苷中的15种发生糖基化。其中,12个核苷在≥25 μmol的规模上成功糖基化,分离收率为39-91%,包括4个目前的治疗方法。
3′-O-β-Glucosylation of nucleoside analogues using a promiscuous bacterial glycosyltransferase†
Nucleoside analogue therapeutics have a proven capability within drug discovery as antiviral and antineoplastic agents. However, their efficacy can be limited by poor cellular uptake, off target toxicity and low bioavailability. Glycosylation of pharmaceutical agents/natural products represents a strategically simple method to modulate pharmacological profiles. Herein, we explore biocatalytic glycosylation of nucleoside analogues. The activity of the nucleoside-specific 3′-O-glycosyltransferase AvpGT from Streptomyces sp. AVP053U2 is investigated toward a panel of both natural and clinically relevant purine and pyrimidine nucleoside analogues. AvpGT demonstrates broad substrate promiscuity, with glycosylation observed by HILIC-MS for 15 of 21 nucleosides tested. Of these, 12 nucleosides were successfully glycosylated on ≥25 μmol scale in 39–91% isolated yields, including four current therapeutics.
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