Crystal packing in three related disaccharides: precursors to heparan sulfate oligosaccharides

\ Heparan sulfate (HS) is a linear polysaccharide with a disaccharide repeating unit of D-glucosamine and L-iduronic or D-glucuronic acid, which can be O- or N-sulfated or N-acetyl­ated. HS is involved in the regulation of many important biological processes (Bishop et al., 2007; Turnbull et al., 2001). Synthetic HS-oligosaccharides with high potency as BACE1 inhibitors might have an application as novel therapeutics for Alzheimer's disease (Schwörer et al., 2013; Scholefield et al., 2003).

In our recent paper (Schwörer et al., 2013), we described the synthesis and inhibition data of a library of such oligosaccharides. At the centre of the synthetic methodology are highly orthogonally protected disaccharide building blocks, three of them being the subjects of this paper. The disaccharides can be converted into glycosyl donors by hydrolysis of the meth­oxy­phenyl glycoside and formation of the corresponding tri­chloro­acemidate; while the azide and the orthogonal ester protecting groups provide selective access to further functionalization later in the synthesis.

While pursuing precursor disaccharides with possible application in the treatment of Alzheimer's disease, we have prepared some ido- and gluco-related crystals of the published gluco-derivative 4-meth­oxy­phenyl 4-O-[6-O-acetyl-2-azido-3-O-benzyl-2-de­oxy-4-O-\ (9-fluorenyl­methyl­oxycarbonyl)-α-D-gluco­pyran­osyl]-2-O-\ benzoyl- 3-O-benzyl-6-O-chloro­acetyl-β-D-gluco­pyran­oside, hereafter RSTE (Gainsford et al., 2013). We have been intrigued that no unambiguous defining set of inter­molecular attractive inter­actions has been observed (Gainsford et al., 2012) for these four structures and three other in-house examples.

\ 4-Meth­oxy­phenyl 4-O-[6-O-acetyl-2-azido-3-\ O-benzyl-2-de­oxy-4-O-(9-\ fluorenyl­methyl­oxycarbonyl)-α-D-gluco­pyran­osyl]-2-\ O-benzoyl-3-O-benzyl-6-\ O-chloro­acetyl-α-L-ido­pyran­oside, (I) (hereafter OZTF)

The crystal contains one independent molecule of the title compound (Fig. 1) with the pyran­ose rings in chair conformations (Table 1). The determined absolute configuration confirmed the expected stereochemistry: C1(S), C2(R), C3(S), C4(S), C5(S), C30(S), C31(R), C32(S), C33(R), C34(R), C47(R). Conformational two-site disorder models were required for the pendant 6-O-chloro­acetyl and methyl of the 6-O-acetyl groups.

(I4-Meth­oxy­phenyl 4-O-[6-O-acetyl-2-azido-3-\ O-benzyl-2-de­oxy-4-O-(9-\ fluorenyl­methyl­oxycarbonyl)-α-D-gluco­pyran­osyl]-2-\ O-benzoyl-3-O-benzyl-6-\ O-methoxyo­acetyl-α-L-\ ido­pyran­oside, (II) (hereafter RNSB)

This molecule (Fig. 2) crystallized in an isostructural cell to (I), as shown in Fig. 3. A comparison of the molecules of (I) and (II) shows that intra­molecular inter­actions seem to determine the near identical atomic configurations (see Figs 1, 2 and 5). As might be expected, only one other weak packing inter­molecular inter­action is found.

4-Meth­oxy­phenyl 4-O-[6-O-acetyl-2-azido-3,4-\ O-benzyl-2-de­oxy-α- D-gluco­pyran­osyl]-2-O-benzoyl-3-\ O-benzyl-6-O-meth­oxy­acetyl-β-\ D-gluco­pyran­oside, (III) (hereafter RSTN)

Compound (III) (Fig. 4) crystallizes with one independent molecule but with disorder on one of the terminal benzyl­oxy groups and the 2-meth­oxy­acet­oxy methyl group, modelled by two-site disorder models. The absolute configuration was not ambiguously determined but is known from the synthetic chemistry.

The conformational data given in Tables 1 and 2 show the essential pyran­ose chair conformations have not been disturbed significantly in the title compounds.

The crystal packing in (I) is provided by weak C—H···O(ether), C—H···O (carbonyl) hydrogen bonds and one C—H···π inter­action (Table 3). These inter­actions form a three-dimensional network in which the base motifs are C(8), C(12) and C(20) (Bernstein et al., 1995; Fig. 5). Given the unusual pseudo-dimeric nature of the hydrogen bonding in the gluco­pyran­oside crystal (Gainsford et al., 2013) and the chloro­acet­oxy group disorder, it is not surprising that there is only one common C—H···O(carbonyl) inter­action involving the C1—H1 atoms. In the isostructural compound (II), the same inter­actions are observed plus one additional methyl­ene-H···O(ether) (C29—H29···O12A) (Table 4); this is only possible in (II) with the difference in composition of the two molecules (the chloro­acetyl being replaced by the meth­oxy­acetyl group).

In (III), the five C—H···O(ether and ketone) inter­actions are augmented by five C—H···π inter­actions (Table 5). These inter­actions form stacks of twofold-related molecules along the b axis in which R₂²(18) and C(n) (n = 5,17) motifs (Bernstein et al., 1995) are present.

There are only a few reported 2-azido pyran­ose-based disaccharide structures in the Cambridge Structural Database (Version 5.36, with February 2015 update; Groom & Allen, 2014): our published gluco­pyran­oside (Gainsford et al., 2013; BILJAJ), a manno­pyran­oside (Luger & Paulsen, 1981; BABHUH) and one ido­pyran­ose (Lee et al., 2004; AQOGIW). We note another disaccharide gluco­pyran­ose (Abboud et al., 1997; RAVNAD) for comparison. The conformational data given in Tables 1 and 2 show the pyran­ose essential chair conformations have not been disturbed significantly, although the ring with the bound azide seems to be closer to a `pure' chair conformation by the θ criteria (Cremer & Pople, 1975).

The title compounds were prepared as described in Schwörer et al. (2013). Crystals were obtained by vapour diffusion of petroleum ether into a solution of the title compounds in ethyl acetate (I) or toluene (II) and (III).

Crystal data, data collection and structure refinement details are summarized in Table 6. Subject to variations noted below, the methyl H atoms were constrained to an ideal geometry (C—H = 0.98 Å) with U_iso(H) = 1.5U_eq(C), but were allowed to rotate freely about the adjacent C—C bonds. All other H atoms were placed in geometrically idealized positions and constrained to ride on their parent atoms with C—H distances of 0.95 (aromatic), 0.99 (methyl­ene) or 1.00 (tertiary) Å with U_iso(H) = 1.2U_eq(C) or 1.5U_eq(C) (for methyl C) of their parent atom. Specific variations were:

(I) Data at resolution less than 1.12 Å was not significantly above the noise level and was excluded from the refinement. One other reflection (1,0,9) was OMITted as an outlier. Data analysis shows that there are many data in the resolution range 1.40–1.12 Å that are in poor agreement reflecting crystal quality.

There was conformational disorder in the chloro­acet­oxy (atoms C28, C29, O9 and Cl1) and the meth­oxy­carbonyl­oxy (atoms C37, C37 and O12) groups which was modelled as two (A and B) groups. Because of proximity, and poor data quality, these atoms were unable to be refined with anisotropic thermal parameters. It proved advisable to add additional restraints to retain known geometries based on published structures for these groups. So (SHELXL DFIX) C28–C29 pairs were held to 1.50 (3) Å; C28—O9 to 1.20 Å and same-distance constraints (SADI, 0.02) were applied to C29–Cl1, C36–C37 and C36–O11. Thermal parameters were also linked using SIMU for ring atoms C6–C11 and atom pairs C53 and C54, O12A and O12B, C37A and C37B, and C36A and C36B. Finally, rings C6–C11 and C14–C19 were constrained to hexagonal geometry with C—C = 1.390 Å. Final A:B occupancies for the chloro­acet­oxy group were 0.509 (17):0.491 (17) and for the meth­oxy­carbonyl­oxy, 0.44 (4):0.56 (4).

(II) Data at resolution less than 0.81 Å was not significantly above the noise level and was excluded from the refinement. Two reflections (17,1,7; 6,9,5) were OMITted as clear outlier data. There was two-site conformational disorder for the methoxyl­acetyl atoms C36 and O12 (labelled A and B, respectively). Atoms C13, C33, C34, C30, C361 and C36B were restrained to isotropic-like behaviour (using ISOR) and the two-model disordered atoms (O12A, O12B; C36A, C36B) were given the same anisotropic thermal parameters. Distant constraints (SADI, 0.3) were applied to the C36A—O12A and C36B—O12B bonds. Final A:B occupancies for the meth­oxy­acetyl atoms were 0.797 (16):0.203 (16).

(III) One reflection was removed as an outlier as well as nine low angle reflections affected by the beamstop (F_o<<F_c). The molecule showed two major orientations for the benzyl group (atoms C13–C19) refined by two refining set occupancies [A:B 0.793 (6):0.207 (6)] coupled with equivalent U values (SIMU for each ring set) and with each ring restrained to a regular hexagon (C—C 1.39 Å). In a similar manner, two orientations of atoms C29, O52 and C52 were refined as two conformations: final A:B ratio 0.687 (8):0.313 (8).