A novel type of nucleoside analogue with penta-coordinated phosphorus

Synthesis and antiproliferative evaluation of novel azido nucleosides and their phosphoramidate derivatives

New xylofuranosyl and glucopyranosyl nucleoside phosphoramidates were synthesized as potential mimetics of nucleoside 5′-monophosphates. Their access involved N-glycosylation of uracil and 2-acetamido-6-chloropurine with 5′/6′-azido-1,2-di-O-acetyl glycosyl donors and subsequent Staudinger-phosphite reaction of the resulting azido nucleosides. The coupling of the purine derivative with the pyranosyl donor furnished N9- and N7-linked nucleosides in 1:1 ratio, whereas with the furanosyl donor, the N9-nucleoside was the major regioisomer formed. When using uracil, only 5′/6′-azido N1-linked nucleosides were obtained. The purine 5′/6′-azido nucleosides were converted into corresponding phosphoramidates in good yields. The antiproliferative effects of the nucleoside phosphoramidates and those of the azido counterparts on cancer cells were evaluated. While the nucleoside phosphoramidates did not show significant activities, the purine 5′/6′-azido nucleosides displayed potent effects against K562, MCF-7 and BT474 cell lines. The 5′-azidofuranosyl N9 and N7-linked purine nucleosides exhibited highest activity towards the chronic myeloid leukemia cell line (K562) with GI50 values of 13.6 and 9.7 μM, respectively. Among pyranosyl nucleosides, the N7-linked nucleoside was the most active compound with efficacy towards all cell lines assayed and a highest effect on K562 cells (GI50=6.8 μM). Cell cycle analysis of K562 and MCF-7 cells showed that the most active compounds cause G2/M arrest.

Biologically relevant phosphoranes: synthesis and structural characterization of glucofuranose-derived phosphoranes with penta- and hexacoordination at phosphorus

Carbohydrate-based phosphoranes were synthesized by reacting the appropriate diphenol with phosphorus trichloride followed by the addition of chloralose to form 1 and by the addition of isopropylidene-D-glucofuranose to form 2 and 3. Phosphorane 4 was obtained by reacting 1,2-O-isopropylidene-alpha-D-glucofuranosyl-3,5,6-phosphite (13) with a diphenol. For the synthesis of 5-9, the appropriate phosphite was reacted with isopropylidene-glucofuranose. X-ray analyses of 1-9 were carried out successfully. Hexacoordinated structures resulted via oxygen donor action at phosphorus in the cases of phosphoranes 1-3 and via sulfur donor action for phosphoranes 4-6. Trigonal bipyramidal structures formed for 7-9 with the carbohydrate components occupying axial-equatorial sites. The eight-membered ring of the diphenol moiety with weak or no donor groups in 7-9 occupied diequatorial sites of the trigonal bipyramid. Solution NMR data are in agreement with the assigned solid-state structures. Isomerism between penta- and hexacoordination is present in solution for 7. The isomerism observed for 7 and our previous study showing a rapid exchange process that reorients the carbohydrate component of the trigonal bipyramidal phosphorane suggest that these biophosphoranes may serve as models for active sites of phosphoryl-transfer enzymes. At an active site, this type of pseudorotational behavior provides a mechanism that could bring another active site residue into play and account for a means by which some phosphoryl-transfer enzymes express promiscuous behavior.

Biologically relevant phosphoranes: structural characterization of a nucleotidyl phosphorane

The first successful crystal structures of biorelevant nucleoside and carbohydrate-based phosphoranes are reported. Employing thymidine, a nucleotidyl phosphorane was synthesized in 90% yield and was shown by X-ray analysis to possess a trigonal bipyramidal geometry. With the use of 1,2-O-isopropylidene-alpha-d-glucofuranose, a carbohydrate-based phosphorane was formed and similarly found to have a trigonal bipyramidal geometry. NMR studies demonstrated the existence of isomerism in solution associated with the nucleotidyl phosphorane and rapid exchange for the carbohydrate-based phosphorane. The geometrical representations reported here are expected to have significant applications associated with active site mechanisms of phosphoryl transfer enzymes, for example, in DNA, RNA, c-AMP, and others.