Synthesis of cyclophospho-glucoses and glucitols

Unprecedented Convergent Synthesis of Sugar-Functionalization of Phosphinic Acids under Metal-Free Conditions

A novel TEA-catalyzed sugar-esterification of phosphinic acids was used as a general and efficient approach for the synthesis of a variety of phosphinates without any transition metal. The high efficiency of the current methodology and a convenient experimental procedure compensate for the moderate yields obtained. Another advantage is that the reaction tolerates different substituents attached to the phosphinic acids and the sugar moieties alongside the ease of isolation of the product.

Phosphonate and α-Fluorophosphonate Analogues of d-Glucose 6-Phosphate as Active-Site Probes of 1l-myo-Inositol 1-Phosphate Synthase

The biosynthesis of myo-inositol (mI) is central to the function of many organisms across all kingdoms of life. The first and rate-limiting step in this pathway is catalyzed by 1l-myo-inositol 1-phosphate synthase (mIPS), which converts d-glucose 6-phosphate (G6P) into 1l-myo-inositol 1-phosphate (mI1P). Extensive studies have shown that this reaction occurs through a stepwise NAD⁺-dependent redox aldol cyclization mechanism producing enantiomerically pure mI1P. Although the stereochemical nature of the mechanism has been elucidated, there is a lack of understanding of the importance of amino acid residues in the active site. Crystal structures of mIPS in the ternary complex with substrate analogues and NAD(H) show different ligand orientations. We therefore proposed to use isosteric and isoelectronic analogues of G6P to probe the active site. Here, we report the synthesis of the methylenephosphonate, difluoromethylenephosphonate, and (R)- and (S)-monofluoromethylenephosphonate analogues of G6P and their evaluation as inhibitors of mIPS activity. While the CH₂ and CF₂ analogues were produced with slight modification of a previously described route, the CHF analogues were synthesized through a new, shorter pathway. Kinetic behavior shows that all compounds are reversible competitive inhibitors with respect to G6P, with K_i values in the order CF₂ (0.18 mM) < (S)-CHF (0.24 mM) < (R)-CHF (0.59 mM) < CH₂ (1.2 mM). Docking studies of these phosphonates using published crystal structures show that substitution of the oxygen atom of the substrate changes the conformation of the resulting inhibitors, altering the position of carbon-6 and carbon-5, and this change is more pronounced with fluorine substitution.

Pyranoid Spirosugars as Enzyme Inhibitors

Background:

Pyranoid spirofused sugar derivatives represent a class of compounds with a significant impact in the literature. From the structural point of view, the rigidity inferred by the spirofused entity has made these compounds object of interest mainly as enzymatic inhibitors, in particular, carbohydrate processing enzymes. Among them glycogen phosphorylase and sodium glucose co-transporter 2 are important target enzymes for diverse pathological states. Most of the developed compounds present the spirofused entity at the C1 position of the sugar moiety; nevertheless, spirofused entities can also be found at other sugar ring positions. The main spirofused entities encountered are spiroacetals/thioacetals, spiro-hydantoin and derivatives, spiro-isoxazolines, spiro-aminals, spiro-lactams, spiro-oxathiazole and spiro-oxazinanone, but also others are present.

Objectives:

The present review focuses on the most explored synthetic strategies for the preparation of this class of compounds, classified according to the position and structure of the spirofused moiety on the pyranoid scaffold. Moreover, the structures are correlated to their main biological activities or to their role as chiral auxiliaries.

Conclusion:

It is clear from the review that, among the different derivatives, the spirofused structures at position C1 of the pyranoid scaffold are the most represented and possess the most relevant enzymatic inhibitor activities. Nevertheless, great efforts have been devoted to the introduction of the spirofused entity also in the other positions, mainly for the preparation of biologically active compounds but also for the synthesis of chiral auxiliaries useful in asymmetric reactions; examples of such auxiliaries are the spirofused chiral 1,3-oxazolidin-2-ones and 1,3-oxazolidine-2-thiones.