Synthesis and Biological Evaluation of Structurally Varied 5'-/6'-Isonucleosides and Theobromine-Containing N-Isonucleosidyl Derivatives.

Nuno M Xavier,M Conceição Oliveira,René Csuk,Immo Serbian,Eduardo C De Sousa,Anne Loesche,Margarida P Pereira

doi:10.3390/ph12030103

Nuno M Xavier, M Conceição Oliveira + Show 5 more

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https://doi.org/10.3390/ph12030103

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Abstract

Isonucleosides are rather stable regioisomeric analogs of nucleosides with broad therapeutic potential. We have previously demonstrated the ability of 5′ and 6′-isonucleosides to inhibit the activity of acetylcholinesterase, a major target for Alzheimer’s disease therapy. Continuing with our research on this topic, we report herein on the synthesis and biological evaluation of a variety of novel terminal isonucleosides and theobromine isonucleotide analogs. Xylofuranose-based purine or uracil 5′-isonucleosides and xylofuranos-5′-yl or glucos-6′-yl theobromine derivatives were accessed via Mitsunobu coupling between partially protected xylofuranose or glucofuranose derivatives with a nucleobase using conventional or microwave-assisted heating conditions. Theobromine-containing N-isonucleosidyl sulfonamide and phosphoramidate derivatives were synthesized from isonucleosidyl acetate precursors. The most active compounds in the cholinesterase inhibition assays were a glucopyranose-based theobromine isonucleosidyl acetate, acting as a dual inhibitor of acetylcholinesterase (AChE, Ki = 3.1 µM) and butyrylcholinesterase (BChE, Ki = 5.4 µM), and a 2-O,4-O-bis-xylofuranos-5′-yl uracil derivative, which displayed moderate inhibition of AChE (Ki = 17.5 µM). Docking studies revealed that the active molecules are positioned at the gorge entrance and at the active site of AChE. None of the compounds revealed cytoxic activity to cancer cells as well as to non-malignant mouse fibroblasts.

Highlights

Isonucleosides are regioisomers of nucleosides in which a nucleobase or an analogous nitrogeneous hetereoaromatic motif is linked to the sugar moiety at a non-anomeric position
Microwave irradiation proved to be a useful tool in the Mitsunobu reaction between 3-O-dodecyl/octyl-1,2-O-isopropylidene xylofuranose with theobromine or adenine, enabling the access to 5 -isonucleosides in shorter reaction times (30-50 min) than those needed in conventional stirring for analogous reactions (>16 h) and in moderate yields
Biological evaluation revealed the ability of a theobromine isonucleosidyl acetate possessing a glucopyranose moiety (21) to inhibit both AChE and BChE at single-digit micromolar concentrations, reinforcing the potential of theobromine isonucleosides as cholinesterase inhibitors

Summary

Introduction

Isonucleosides are regioisomers of nucleosides in which a nucleobase or an analogous nitrogeneous hetereoaromatic motif is linked to the sugar moiety at a non-anomeric position. This group of structures has attracted significant interest in the search of new nucleos(t)ide analogs, owing to the therapeutic potential of these groups of compounds, especially as anticancer and antiviral agents [1,2]. The lack of an N-glycosidic bond in isonucleosides linking the sugar and nucleobase moieties confers them a higher chemical and enzymatic stability than that of nucleosides. Pharmaceuticals 2019, 12, 103 Pharmaceuticals 2019, 12, x FOR PEER REVIEW.

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