Two isomeric cucurbitane derivatives

Cucurbitacins, a large group of tetracyclic triterpenes, have the 19(10→9 b)abeo-lanostane (cucurbitane) carbon skeleton. These natural products have been isolated from various plants (Lavie & Glotter, 1971; Chen et al., 2005, and references cited therein; Miró, 1995). Cucurbitacins attract considerable attention owing to their unique structural features, multi-functionality and diverse biological activities (Chen et al., 2005; Miró, 1995).

The cucurbitacins are biogenetically derived from 2,3-oxidosqualene via 10α-cucurbita-5,24-diene-3β-ol (cucurbitadienol) as the crucial intermediate (Shibuya et al., 2004). In chemical synthesis, the cucurbitane derivatives are available from the reaction of 9-substituted lanostane derivatives via C-9 carbocationic intermediates (Paryzek, 1976, 1979; Edwards & Paryzek, 1983; Edwards & Kolt, 1987).

Several crystallographic analyses of cucurbitacins have aimed to establish unambiguously the structure of compounds isolated from natural sources. Besides other characteristic features, most natural cucurbitacins are characterized by the presence of the 5,6-double bond in the carbon skeleton. Accordingly, X-ray data for a number of cucurbit-5-ene derivatives have been accumulated, namely 10α-cucurbitadienol C-3 acetate (Nes et al., 1991), cucurbit-5-ene-3,22,23,24,25-pentaol (Okabe et al., 1980), (20R)-16-α-acetoxy-20-hydroxy-24,25,26,27-tetranor- 2β-(β-D-tetra-acetylglucopyranosyloxy)-10α-cucurbit-5-en-3,11, 22-trione trihydrate (Weinges et al., 1989), cucurbitacin E (Wu et al., 2004), 3β-hydroxy-7β,25-dimethoxycucurbita- 5,23(E)-diene (Harinantenaina et al., 2006), datiscoside bis-(p-iodobenzoate) dihydrate(Restivo et al., 1973), datiscoside dibenzene solvate (Sasamori et al., 1983) and 3β,16β-dihydroxy-7β-ethoxycucurbita-5,24-diene (Fujimoto et al., 1986).

In our investigation of the Lewis acid catalyzed reaction of 9β,11β-epoxy-5α-lanostane derivative, a series of compounds having the rearranged lanostane skeleton have been isolated and characterized. Spectroscopic methods (mostly ¹H and ¹³C NMR) identified two compounds as the cucurbit-5(10)-ene and 5α-cucurbit-1(10)-ene derivatives, indicating the presence of the double bond in a rather unusual position in ring B (Figs. 1 and 2 show the nomenclature of the rings). There are only a few structurally characterized compounds with the 5(10)-ene steroid skeleton and even fewer with the 1(10)-ene analogue. A search of the Cambridge Structural Database (Allen, 2002; Version 5.30, November 2008), using a search fragment that excluded additional fused rings, gave 11 hits for the former and only two for the latter. We report here the crystal structures of the isomeric 5(10)-ene and 1(10)-ene cucurbitane derivatives 3β,7α,11β-triacetoxycucurbit-5(10)-ene, (I), and 3β,7α,11β-triacetoxy-5α-cucurbit-1(10)-ene, (II).

Crystals of both (I) and (II) proved very difficult to grow, resulting in samples of limited diffraction quality. We related this to the presence in both structures of disorder, which persisted despite the data collection temperature being lowered to 100 (1) K for (I) and to 190 (1) K for (II). The higher temperature employed for (II) was mandated by a decline in diffraction quality upon further cooling. The disorder affects the chain fragments; the alternative positions were resolved for five terminal atoms in molecule A of (I), (IA), with site-occupancy factors of 0.7/0.3, for four atoms in molecule B of (I) [(IB), 0.5/0.5] and for three atoms in (II) [0.631 (13)/0.369 (13)].

In (I), there are two symmetry-independent molecules in the asymmetric part of the unit cell. A normal probability plot (International Tables for X-ray Crystallography, 1974, Vol. IV, pp. 293–309; Abrahams & Keve, 1971) shows that the differences between the independent molecules in this case are statistical only and not systematic in nature. For the bond lengths in the ordered part of the molecule, the correlation factor R² between the experimental and theoretical values is 0.96, the deviation of the a parameter (or slope in y = ax + b, in this case y = 1.64x - 0.05) from unity points to the typical underestimation of the s.u. values, while the small value of the b parameter indicates the lack of systematic errors. There is, in fact, quite good pseudo-twofold symmetry axis along the c-axis direction, which connects the main parts of those otherwise independent molecules. For the ordered part of the molecules the mean values of the combination of the coordinates (x_A + x_B, y_A + y_B, z_A - z_B) are 1.122 (7), 2.001 (3) and -0.001 (4), consistent with an approximate twofold axis along z at (0.561, 1.000, z).

The bond lengths and angles are close to typical values; the mean values of the Csp³—Csp³ bonds are 1.54 (2) Å in both structures. The relevant parameters that establish the location of the endocyclic C═C double bonds are C5A═C10A [1.352 (5) Å] and C5B═ C10B [1.334 (5) Å] in (I), and C1═C10 [1.333 (4) Å] in (II).

The different placement of the double bond heavily influences the conformations of the four-ring skeletons, and it is notable that the two symmetry-independent molecules in (I) have very similar conformations. In (I), rings A and B are close to the half-chair conformation (B less so than A), with an almost coplanar ring junction. In (II), ring A is again close to half-chair, of course with a different location for the approximate local twofold axis, but ring B is closer to a distorted twist-boat conformation, and the ring junction is cisoid. The most unexpected differences are observed in the conformations of ring C, apparently unaffected by the differences in ring A. The former is close to a standard chair conformation in (I), while in (II) this conformation can be described as a distorted boat. This latter conformation has not been observed previously in any of the steroids having a similar ring structure with a double bond in either the C1═C10 or C5═C10 positions. The B/C junction is cis in (I), but in (II) it is significantly flattened; the torsion angles around the junction bond C8—C9 are -18.4 (4) and 2.3 (4)°. Finally, rings D are quite regular half-chairs in both structures. The symmetry of the rings can be described by referring to the ideal symmetry, using so-called asymmetry parameters (Duax & Norton, 1975; see Table 2). The orientation of some of the acetoxy groups also differs in the two isomers. The 3β acetoxy group is in the equatorial position in (I), while it is in the axial position in (II), while the 11β substituent is closer to an axial position in (I), but almost in an equatorial position in (II). The 7α acetoxy group is in both compounds in the equatorial position, and the methyl groups C18, C19 and C30 are all axial.

The alkyl chain disorder illustrated in Fig. 3 is observed at both room and lower temperature, suggesting that it is static rather than dynamic in nature. The conformation along the chain (C20···C26 and C20···C27) can be described as g^-ttg⁺ and g^-ttt (g⁺ttg⁺ and g⁺ttt) in (IA), g^-ttg^- and g^-ttg⁺ (g^-ttt and g^-ttg^-) in (IB), and g⁺ttg⁺ and g⁺ttt (g⁺ttg^- and g⁺ttg⁺) in (II). The symbols in parentheses refer to the second alternative position of the chain.

The crystal structure of (I) features a number of relatively weak but directional C—H···O contacts (Table 1) which are generally symmetrical with respect to both symmetry-independent molecules (cf. C2, C21 and C29), and they connect both kinds of molecules (i.e. there are A···B contacts as well as A···A and B···B ones). The structure of (II) lacks such contacts.