CONFORMATION OF a-D-GLUCOPYRANOSE-1-PHOSPHATE ANION vs POLYMORPHISM OF DIRUBIDIUM GLUCOSE-1-PHOSPHATE DIHYDRATE CRYSTALS

Krystyna Stepniak, Tadeusz Lis^*, Bozena Klimek, Anna E. Koziol

Faculty of Chemistry, Maria Curie-Sk3odowska University, 20-031 Lublin, Poland;
E-mail: akoziol@hermes.umcs.lublin.pl
^* Faculty of Chemistry, University of Wroc3aw, 50-383 Wroc3aw, Poland

Keywords: a-D-glucopyranose-1-phosphate, dirubidium glucose-1-phosphate dihydrate, polymorphism

The pyranose ring, a central part of the a-D-glucopyranose-1-phosphate anion (G1P), adopts the 1C conformation with equatorial substituents at C2, C3, C4 and C5 [1-3]. The conformational changes of the molecule are limited to the rotations of the phosphate and hydroxymethylene groups around the C1-O1 and C5-C6 bonds, respectively. The O5-C1-O1-P torsion angle is in the range 64-90, while two observed solid state orientations of the hydroxyl O6 atom with respect to the pyranose are:

I (+sc, -sc) or E - in G1PHK [1] and G1P 2Na 3.5 H₂O [2] crystals, and

II (+ap, +sc) or Z - in G1P 2K 2H₂O salt [3].

The crystallization of G1P 2Rb from the H₂O / iPrOH / EtOH solvent mixture at 10C gives several forms of crystals, all of them are dihydrates.

form I form II

Fig.1.

Crystal structure of polymorphs depends on the time of crystallization and pH. At the beginning, an unstable phase is formed, which is the orthorhombic form I (the space group P2₁2₁2). Three modifications of this form have been isolated: Ia, Ib and Ic. Each of them contains partially disordered Rb⁺ cations with different occupancy factors, and additionally, disordered water molecule is present in Ic. The second stable orthorhombic form II (with the space group P2₁2₁2₁) is a product of a long-time crystallization process.

The monotropic phase transition I ---> II is composed of two transformations:

(a) the reorientation of the O6 atom in the G1P anion (Fig.1), corresponding to the E ---> Z conformation change;

(b) disorder --- > order transformation of the Rb⁺ cation positions with resulting g differences in cation-anion, cation-water and cation-cation interactions (Fig. 2).

	Rb1: s.o.f. = 1; CN = 7 Rb2: s.o.f. = 0.5; CN = 6 Rb3a: s.o.f. = 0.05 ; CN = 4 Rb3b: s.o.f. = 0.175; CN = 6 Rb3c: s.o.f. = 0.175; CN = 5 Rb3d: s.o.f. = 0.1; CN = 5
Fig. 2.	Rb1: s.o.f. = 1; CN = 8 Rb2: s.o.f. = 1; CN = 7

1. T. Lis, Carbohydr. Res. 229 (1992) 33-39.
2. A.E. Koziol, Polish J. Chem. 65 (1991) 455-463.
3. Y. Sugawara, H. Iwasaki, Acta Cryst. C40 (1984) 389-393.