Molecular dynamics simulations of the two disaccharides of hyaluronan in aqueous solution

Andrew Almond, John K. Sheehan, Andy Brass

    Research output: Contribution to journalArticlepeer-review

    Abstract

    Hyaluronan is an unusually stiff polymer when in aqueous solution, which has important consequences for its biological function. Molecular dynamics simulations of hyaluronan disaccharides have been performed, with explicit inclusion of water, to determine the molecular basis of this stiffness, and to investigate the dynamics of the glycosidic linkages. Our simulations reveal that stable sets of hydrogen bonds frequently connect the neighboring residues of hyaluronan. Water caging around the glycosidic linkage was observed to increase the connectivity between sugars, and further constrain them. This, we propose, explains the unusual stiffness of polymeric hyaluronan. It would allow the polysaccharide to maintain local secondary structure, and occupy large solution domains consistent with the visco-elastic nature of hyaluronan. Simulations in water showed no significant changes on inclusion of the exoanomeric effect. This, we deduced, was due to hyaluronan disaccharides ordering first shell water molecules. In some cases these waters were observed to transiently induce conformational change, by breaking intramolecular hydrogen bonds.
    Original languageEnglish
    Pages (from-to)597-604
    Number of pages7
    JournalGlycobiology
    Volume7
    Issue number5
    DOIs
    Publication statusPublished - Jul 1997

    Keywords

    • Conformation
    • Hyaluronan
    • Hydrogen bonds
    • Molecular dynamics
    • Water

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