Hyaluronic acid: molecular conformation and interactions in the tetragonal form of the potassium salt containing extended chains.

X-ray diffraction data were used to determine the detailed crystal structure of a tetragonal form of potassium hyaluronate containing relatively extended 4-fold helical chains (rise per disaccharide h = 0.95 nm). The polysaccharide chains are left-handed (4(3] helices. Two antiparallel chains pack in a tetragonal unit cell (a = b = 0.996 nm, c = 3.788 nm) with P4(3)2(1)2 space group symmetry. The chain conformations are stabilized intramolecularly by O4-O5 hydrogen bonds across the beta(1 leads to 3) linkage and by a pair of intermolecular hydrogen bonds per disaccharide between adjacent antiparallel chains. Fourier difference synthesis revealed one potassium ion and two water molecules per disaccharide. Six polyanion oxygen atoms from three neighboring chains together with one of these water molecules form the co-ordination polyhedra. Further stability is brought about through inter- and intrachain water bridges involving both water molecules. The probable reason for the stability of this extended allomorph is discussed in terms of the preferred co-ordination geometry of the potassium ion.