Chemoenzymatic synthesis of sulfur-linked sugar polymers as heparanase inhibitors

Complex carbohydrates (glycans) are major players in all organisms due to their structural, energy, and communication roles. This last essential role involves interacting and/or signaling through a plethora of glycan-binding proteins. The design and synthesis of glycans as potential drug candidates...

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Bibliographic Details
Published in:Nature communications 2022-12, Vol.13 (1), p.7438-12, Article 7438
Main Authors: He, Peng, Zhang, Xing, Xia, Ke, Green, Dixy E., Baytas, Sultan, Xu, Yongmei, Pham, Truong, Liu, Jian, Zhang, Fuming, Almond, Andrew, Linhardt, Robert J., DeAngelis, Paul L.
Format: Article
Language:English
Subjects:
631/45/221
631/45/535/878/1263
631/61
639/638/309/2420
639/638/92/72/1205
Analogs
Binding
Carbohydrates
Chemical synthesis
Copolymerization
Drug development
Glucuronidase
Glycan
Heparan sulfate
Heparin
Humanities and Social Sciences
Humans
Inhibitors
Modulators
Molecular dynamics
multidisciplinary
Polymers
Polysaccharides
Proteins
Saccharides
Science
Science (multidisciplinary)
Sugar
Sugars
Sulfhydryl Compounds
Sulfur
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Summary:Complex carbohydrates (glycans) are major players in all organisms due to their structural, energy, and communication roles. This last essential role involves interacting and/or signaling through a plethora of glycan-binding proteins. The design and synthesis of glycans as potential drug candidates that selectively alter or perturb metabolic processes is challenging. Here we describe the first reported sulfur-linked polysaccharides with potentially altered conformational state(s) that are recalcitrant to digestion by heparanase, an enzyme important in human health and disease. An artificial sugar donor with a sulfhydryl functionality is synthesized and enzymatically incorporated into polysaccharide chains utilizing heparosan synthase. Used alone, this donor adds a single thio-sugar onto the termini of nascent chains. Surprisingly, in chain co-polymerization reactions with a second donor, this thiol-terminated heparosan also serves as an acceptor to form an unnatural thio-glycosidic bond (‘ S -link’) between sugar residues in place of a natural ‘ O -linked’ bond. S -linked heparan sulfate analogs are not cleaved by human heparanase. Furthermore, the analogs act as competitive inhibitors with > ~200-fold higher potency than expected; as a rationale, molecular dynamic simulations suggest that the S -link polymer conformations mimic aspects of the transition state. Our analogs form the basis for future cancer therapeutics and modulators of protein/sugar interactions. Heparin is a family of complex carbohydrates binding to proteins to modulate cell activities. Here the authors report the synthesis, and conformations simulations of S -linked hemi-A heparosan [GlcA-S-GlcNAc] n , a thio-glycosidic uncleavable polysaccharide, and test it as human heparanase inhibitor.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-022-34788-3