Olaf R. Ludek

Synthesis and conformational analysis of locked carbocyclic analogues of 1,3-diazepinone riboside, a high-affinity cytidine deaminase inhibitor.

Cytidine deaminase (CDA) catalyzes the deamination of cytidine via a hydrated transition-state intermediate that results from the nucleophilic attack of zinc-bound water at the active site. Nucleoside analogues where the leaving NH3 group is replaced by a proton and prevent conversion of the transition state to product are very potent inhibitors of the enzyme. However, stable carbocyclic versions of these analogues are less effective as the role of the ribose in facilitating formation of hydrated species is abolished. The discovery that a 1,3-diazepinone riboside (4) operated as a tight-binding inhibitor of CDA independent of hydration provided the opportunity to study novel inhibitors built as conformationally locked, carbocyclic 1,3-diazepinone nucleosides to determine the enzyme’s conformational preference for a specific form of sugar pucker. This work describes the synthesis of two target bicyclo[3.1.0]hexane nucleosides, locked as north (5) and south (6) conformers, as well as a flexible analogue (7) built with a cyclopentane ring. The seven-membered 1,3-diazepinone ring in all the three targets was built from the corresponding benzoyl-protected carbocyclic bis-allyl ureas by ring-closing metathesis. The results demonstrate CDA’s binding preference for a south sugar pucker in agreement with the high-resolution crystal structures of other CDA inhibitors bound at the active site.

Synthesis of Conformationally North-Locked Pyrimidine Nucleosides Built on an Oxabicyclo(3.1.0)hexane Scaffold

Beginning with a known 3-oxabicyclo[3.1.0]hexane scaffold (I), the relocation of the fused cyclopropane ring bond and the shifting of the oxygen atom to an alternative location engendered a new 2-oxabicyclo[3.1.0]hexane template (II) that mimics more closely the tetrahydrofuran ring of conventional nucleosides. The synthesis of this new class of locked nucleosides involved a novel approach that required the isocyanate II (B = NCO) with a hydroxyl-protected scaffold as a pivotal intermediate that was obtained in 11 steps from a known dihydrofuran precursor. The completion of the nucleobases was successfully achieved by quenching the isocyanate with the lithium salts of the corresponding acrylic amides that led to the uracil and thymidine precursors in a single step. Ring closure of these intermediates led to the target, locked nucleosides. The anti-HIV activity of 29 (uridine analogue), 31 (thymidine analogue), and 34 (cytidine analogue) was explored in human osteosarcoma (HOS) cells or modified HOS cells (HOS-313) expressing the herpes simplex virus 1 thymidine kinase (HSV-1 TK). Only the cytidine analogue showed moderate activity in HOS-313 cells, which means that the compounds are not good substrates for the cellular kinases.

Synthesis of carbocyclic nucleotides as potential substrates for thymidylate kinase.

Enantiomerically pure carbocyclic 2′-deoxy-3′-azidothymidine monophosphate (AZTMP) and carba-2′deoxy-3′-thiocyanatothymidine monophosphate were synthesized to study their behavior toward their phosphorylation by thymidylate kinase. The nucleotides were synthesized starting from the parent nucleosides by an alkaline hydrolysis of the corresponding cycloSal-phosphate triesters.

Synthesis of Carbocyclic Analogues of Thymidine

Abstract A new route towards an enantiomerically pure carbocyclic 2′-deoxyribonucleoside precursor was developed. After coupling with a nucleobase the product is easily accessible for further modifications at the 3′-hydroxy group.