Inhibition of carbohydrate processing enzymes is a topic of great interest, as these enzymes are involved in a plethora of key biochemical events, such as digestion, lysosomal catabolism of glycoconjugates and post-translational glycoprotein processing. Among the most potent inhibitors of such enzymes, iminosugars have emerged as versatile tools for medicinal chemists, especially those in quest for new therapeutic agents. Supply of iminosugars from natural sources or by chemical synthesis has provided excellent targets for medical intervention, ranging from antidiabetics and antivirals to inhibitors of genetic disorders. Although a huge body of literature has been reported around iminosugars, most data have focused on D-series iminosugars, whereas relatively little attention has been devoted to the corresponding L-enantiomers, due to their supposed lack of biological activity profile, as well as their scarce availability from natural sources. Notwithstanding, recent insights into the molecular details of enzyme-inhibitor interactions have led to a reassessment of L-iminosugars for pharmaceutical purposes. On one hand, they have been used as tools for intensive SAR (structure-activity-relationship) studies, in order to gain new information on the enzymatic inhibition mechanisms. Likewise, early reports on biological activity of L-iminosugars have led to reconsider their therapeutic skills. This review focuses on the most significant discoveries regarding medicinal chemistry of L-iminosugars. The important role L-iminosugars play in unravelling the inhibition mechanisms of specific enzymes is herein recognized; moreover, the high potential of this class of inhibitors as novel drug candidates is under discussion.
The development of tumor-targeting drug delivery systems, able to selectively transport cytotoxic agents into the tumor site by exploiting subtle morphological and physiological differences between healthy and malignant cells, currently stands as one of the most attractive anticancer strategies used to overcome the selectivity problems of conventional chemotherapy. Owing to frequent overexpression of folate receptors (FRs) on the surface of malignant cells, conjugation of cytotoxic agents to folic acid (FA) via suitable linkers have demonstrated to enhance selective drug delivery to the tumor site. Herein, the chemical synthesis and biological evaluation of two novel folate-conjugates bearing the anticancer agent chlorambucil (CLB) tethered to either an aminoether (4,7,10-trioxa-1,13-tridecanediamine) or a pseudo-β-dipeptide (β-Ala-ED-β-Ala) linker is reported. The two drug delivery systems have been prepared in high overall yields (54% and 34%) through straightforward and versatile synthetic routes. Evaluation of cell specificity was examined using three leukemic cell lines, undifferentiated U937 (not overexpressing FRs, FR(-)), TPA-differentiated U937 (overexpressing FRs, FR(+)), and TK6 (FR(+)) cells. Both conjugates exhibited high specificity only to FR(+) cells (particularly TK6), demonstrating comparable antitumor activity to CLB in its free form. These data confirm the reliability of folate-based drug delivery systems for targeted antitumor therapy; likewise, they lay the foundations for the development of other folate-conjugates with antitumor potential.
The highly stereocontrolled de novo synthesis of l-NBDNJ (the unnatural enantiomer of the iminosugar drug Miglustat) and a preliminary evaluation of its chaperoning potential are herein reported. l-NBDNJ is able to enhance lysosomal α-glucosidase levels in Pompe disease fibroblasts, either when administered singularly or when coincubated with the recombinant human α-glucosidase. In addition, differently from its d-enantiomer, l-NBDNJ does not act as a glycosidase inhibitor.
The combined use of silanes (Et3SiH or PMHS) and I2 as novel N-glycosidation reagents for the synthesis of bioactive oxathiolane nucleosides 3TC and FTC is reported. Both systems (working as anhydrous HI sources) were devised to act as substrate activators and N-glycosidation promoters. Excellent results in terms of chemical efficiency and stereoselectivity of the reactions were obtained; surprisingly, the nature of the protective group at the N4 position of (fluoro)cytosine additionally influenced the stereochemical reaction outcome.
Last years have witnessed enormous progresses in glycomic field, mainly as a consequence of the crucial role carbohydrates have shown in biological systems. While up to a few years ago attention was mainly focused on the use of easily available D-sugars, a recent interest has emerged around their L-enantiomers, as they have been found to be key components of several bioactive compounds, whether in the form of oligosaccharides, glycopeptides, terpene glycosides or other clinically useful agents. However, L-sugars (L-hexoses especially) are rather rare in nature and not easily accessi-ble from inexpensive sources. As demand for their synthesis in considerable amount and high purity is more and more pressing, intense efforts have been addressed to the development of new and general methodologies for their construction. This review covers the synthetic routes to L-hexoses, mainly those coming from the new century. Methodologies for monosaccharide assembly will comprise de novo approaches, based on carbon chain elongation, hetero Diels-Alder reaction, asymmetric dihydroxylation up to the most recent amino acid-catalyzed aldol addition – as well as D-sugar manipulation strategies, including epimerization by chemical or enzymatic methods. Application of such protocols for the construction of biologically relevant oligosaccharides and natural products will be also briefly mentioned
The study of the base-pairing properties of nucleic acids with sugar moieties in the backbone belonging to the L-series (β-L-DNA, β-L-RNA, and their analogs) are reviewed. The major structural factors underlying the formation of stable heterochiral complexes obtained by incorporation of modified nucleotides into natural duplexes, or by hybridization between homochiral strands of opposite sense of chirality are highlighted. In addition, the perspective use of L-nucleic acids as candidates for various therapeutic applications, or as tools for both synthetic biology and etiology-oriented investigations on the structure and stereochemistry of natural nucleic acids is discussed.
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