Chemicals

Turkesterone (1) was isolated from Ajuga turkestanica (Usmanov et al., 1975). 20-Hydroxyecdysone (6) was supplied by Dr. V. Volodin (Institute of Biology, Russian Academy of Sciences). Muristerone A (9) was purchased from Simes spa, Italy. Other ecdysteroids were generous gifts from other researchers (see acknowledgements in Dinan et al., 1999). Acyl anhydrides were purchased from Sigma/Aldrich. Solvents were analytical or HPLC-grade and used without further purification, with the exception of pyridine, which was dried over sodium hydroxide pellets for at least 24 h before use. All other chemicals were obtained from Sigma-Aldrich Co. (Poole, Dorset, U.K.) or Lancaster Synthesis (Morecambe, Lancs., U.K.).

NMR

¹H and ¹³C nuclear magnetic spectroscopy was performed on a Varian Unity 300 spectrometer (at CSIC, Barcelona) or on a Bruker DMX500 MHz spectrometer (NMR Service, University of Barcelona). Samples were dissolved in the indicated solvent. Chemical shifts are given in ppm and the coupling constants and widths at half height (ω_1/2) are given in Hz. Spectral assignments were achieved by comparison to published data where available (Lafont et al., 2002).

Mass spectrometry

CIMS and FABMS spectra were recorded at the Ecole Normale Supérieure (Paris, France) on a Jeol MS 700 spectrometer equipped with a direct inlet probe. CIMS spectra were recorded in chemical ionisation/desorption mode using ammonia as the reagent gas.

UV spectrophotometry

Ultra-violet spectra of ecdysteroids were determined in methanol using a Shimadzu UV-2401 PC UV-VIS dual-beam spectrophotometer and quartz cells (Hellma, Essex, U.K.). Extinction coefficients were obtained from Lafont et al. (2002).

Thin-layer chromatography

TLC was performed on Merck 60 F₂₅₄ pre-coated 10 × 10 cm plates (BDH, Poole, U.K.), with CHCl₃/EtOH (9:1 v/v) for development and visualisation by fluorescence quenching under short-wavelength UV light.

Solid-phase extraction

Reversed-phase (C₁₈; 0.5g) Sep-Pak cartridges (Waters/Millipore, Watford, U.K.) were activated with methanol (5 mL), followed by water (10 mL). The sample was applied in 10% aq. MeOH and then the column was sequentially eluted with 5 mL portions of 10%, 25% and 100% aq. MeOH.

HPLC

Two HPLC systems were employed. The analytical system consisted of a Gilson model 811 HPLC coupled with a Gilson 160 diode-array detector and controlled by Gilson Unipoint program. The semi-preparative system consisted of two Gilson model 303 pumps, a model 802c manometric module, a mixing unit, a Holochrome variable wavelength detector and Rheodyne 7125 injector block. Solvent composition and flow was controlled by an Apple IIe computer with Gilson Gradient Manager program. Elution profiles were monitored at 242 nm. Three types of column were used: i) Spherisorb reversed-phase octadecyl (ODS2) column (analytical: 150 mm × 4.6 mm i.d., 5 µm particle size; semi-preparative: 250 mm × 10 mm i.d. 5 µm particle size), ii) normal-phase Zorbax SIL column (analytical: 250 mm × 4.6 mm i.d. 5 µm particle size), iii) normal-phase Apex II DIOL column (analytical: 250 mm × 4.6 mm i.d., 5 µm particle size). Columns were purchased from Jones Chromatography, Hengoed, Wales.

Synthesis of 11α-acyl derivatives of turkesterone

Synthesis of turkesterone acetates

Purity of test compounds

All compounds for bioassay were purified by RP-HPLC using water/methanol mixtures. Purity of samples for bioassay was >98%.

B_II bioassay

The microplate-based B_II bioassay, based on the ecdysteroid-responsive D. melanogaster l(2)mbn permanent cell line, was performed as described previously (Clément et al., 1993).

Competitive radioligand binding assay with in vitro-expressed receptor complexes

Bacterially-expressed DmEcR and DmUSP proteins were used in a competitive binding assay with [24,25,26,27-³H]ponasterone A (0.2 nM; 150 Ci/mmol; ARC Inc.) as previously described (Dinan et al., 2001). K_i values were calculated from IC₅₀ values by means of the Cheng-Prusoff equation (K_i = IC₅₀/{1 + [radiolabelled ligand]/K_d}; Cheng and Prusoff, 1973), with the K_d for [³H]ponA being 0.15 nM.

Extraction of receptor complexes from B_II cells and cell-free receptor assays

Ecdysteroid receptor complexes were extracted from B_II cells by sonication as described previously (Dinan, 1985). After centrifugation (20,000 × g for 30 min), aliquots of the supernatant were incubated with [³H]ponA (0.2 nM; 183 Ci/mmol) and known concentrations of the test compounds. Specifically-bound radiolabel was determined by dextran-coated charcoal assay (Dinan, 1985). K_d values were determined by the LIGAND program.

Regioselective synthesis of 11α-acyl derivatives of turkesterone

Owing to the presence of several reactive secondary hydroxyl groups in turkesterone, it was necessary to protect the diols at C-2/C-3 and C-20/C-22 in order to selectively acylate the 11α-hydroxyl. The acylation sequence of the hydroxyls in 20-hydroxyecdysone has been investigated previously (Galbraith and Horn, 1969) and found to be: 2>22>3≫25. Acetylation experiments comparing turkesterone and 20-hydroxyecdysone indicated that the sequence for turkesterone was 2>11>22>3≫25 (data not shown). Figure 2 demonstrates the protection strategy employed. The 20,22-phenylboronate was first produced, followed by the 2,3-acetonide derivative. The 11α-hydroxyl group could then be derivatised with the appropriate acyl anhydride. Conditions for this reaction had to be modified to take account of the solid state and lower solubility of the higher acyl anhydrides relative to their lower homologues. The diol-protecting groups were readily removed with dilute acid. Overall yields for the 11α-acyl derivatives were variable. The synthesis of turkesterone 11α-benzoate was attempted, but the product proved unstable, degrading rapidly back to turkesterone.

Identification of turkesterone derivatives

Turkesterone derivatives were identified by a combination of ¹H and ¹³C NMR and mass spectrometry. The major distinctive ¹H-NMR features amongst the compounds were the presence of one or more singlet absorptions at ca. δ 2.0 due to the acetyl groups for the acetates, and the shifts of ca. 1 ppm for the acylated oxymethine in acyl analogues. In the homogeneous series of 11α-acyl analogues, significant differences were only observed in the number of signals in the ¹³C-NMR associated with the length of the acyl chain. Diagnostic absorptions are reported for all compounds and selected representatives were fully characterized by NMR. Minor differences were observed in the 11-O-acyl series and the expected shifts upon acylation of other positions.

¹H NMR for 11α-acyl derivatives

The most noticeable change from the spectrum for turkesterone was the shift in the H-11 signal from δ4.1 to δ5.3. The signal for the acyl methyl (CH₃) was present at δ0.8–0.9 and signals at δ1.3–2.3 related to the acyl CH₂ groups.

¹³C NMR for 11α-acyl derivatives

A small shift in the C-11 signal from δ69.5 in turkesterone to δ71–72 was apparent for all acyl derivatives. The acyl carbonyl (C=O) was identified by a signal at δ171–173, the acyl methyl was identified by a signal at δ14 and the acyl CH₂ groups were identified by a sequence of signals around δ22–35.

¹H NMR for acetate derivatives

2ax-H and 3eq-H seen at δ4.01 and δ3.95, respectively, in turkesterone displayed downfield shifts to δ5.1–5.3 and δ4.1–4.2, respectively, upon derivatization at C-2. Similarly the peak for 11-H seen at δ4.1 in turkesterone was seen at δ5.3–5.6 in derivatives containing an acetate at C-11, and the signal for 22-H, seen at δ3.44 in turkesterone, shifted to δ4.8 upon derivatization at C-22. Acetyl (CH₃) signals were apparent at δ2.0–2.1.

¹³C NMR for acetate derivatives

Only minor shifts were observed for signals corresponding to C-2, C-3, C-11 and C-22 for compounds derivatised at C-2, C-11 and/or C-22 (from δ68.9, 68.6, 69.5 and 78.4 for turkesterone to δ71.2, 65, 71 and 79, respectively, for derivatised compounds). The acetyl carbonyl (C=O) was the most obvious addition to the spectra at ca. δ170 while the acetyl (CH₃) signals could be identified at ca. δ21.

Biological activity of turkesterone 11α-acyl derivatives

B_II bioassay: The biological activity of turkesterone in the B_II bioassay is ca. 100-fold lower than that of 20E (Table 5). It is notable that all the tested derivatives of turkesterone retain quantifiable biological activity in this bioassay, but their activities range from almost identical to over 1000-fold less than that of turkesterone. When one compares the activities of the various 11α-acyl homologues, biological activity initially decreases with increasing acyl chain length (C₂ to C₄) with the acetate, propionate and butanoate being 5-, 10- and 50-fold less active than turkesterone. However, with intermediate length acyl groups (C₆ to C₁₄) the activity increases again, such that the activities of the 11α-decanoate, -laurate and -myristate are similar to that of turkesterone. Activity is again lower with the C₂₂ arachidate ester (27.5-fold lower than turkesterone). These data indicate that the ligand binding pocket of EcR is capable of accepting steric bulk around C-11 of the ecdysteroidal ligand and that, further, interaction between the ligand and the binding pocket is enhanced with medium-chain length acyl groups (C₁₀ - C₁₄), relative to short- and long-chain acyl derivatives. Turkesterone 2-acetate has a biological activity similar to that of turkesterone 11α-acetate, in accord with previous observations that small substituents at C-2 lower activity, but do not abolish it. The diacetates, 2,11- and 2,22-, have very much lower activities than turkesterone, but the 2,11-diacetate is more active than the 2,22-diacetate, again revealing that derivatisation at 11α is less detrimental than at C-22.

In vitro receptor assays: In addition to receptor affinity, a number of factors (e.g. penetration into the cells, sequestration, hydrolysis of ester-containing compounds) might affect potency in the B_II bioassay. Consequently, the ability of certain of the test compounds to displace [³H]ponA from in vitro-expressed DmEcR/DmUSP receptor complex was assessed (Table 5). Owing to limited quantities of the DmEcR and DmUSP proteins, it was not possible to assess all of the analogues. Comparison of the receptor assay with the B_II bioassay reveals a distinct difference between 20E and turkesterone. While 20E is more potent in the B_II bioassay (EC₅₀ = 7.5 × 10⁻⁹M) than in the receptor assay (K_i = 5.2 × 10⁻⁸M), turkesterone is, conversely, ca. 9-fold less potent in the B_II bioassay (EC₅₀ = 8.0 × 10⁻⁷M) than in the receptor assay (K_i = 9.0 × 10⁻⁸M). This implies that other factors (entry, efflux, sequestration or metabolism) affect turkesterone and 20E differentially. It is known that the B_II cells do not metabolise 20E (Dinan, 1985). The differential activities in the two systems may relate to previous findings that turkesterone is a potent ecdysteroid in some insect systems, but not in others (Sláma et al., 1993). Alternatively, it may indicate that the in vitro preparation has the capacity to dehydrate 11α-hydroxyl ecdysteroids to 7,9(11)-dien-6-ones (which are known to be biologically active) by a chemical reaction which occurs readily (Bourne et al., 2002).

However, there is good agreement between the K_i and EC₅₀ values for the 11α-acyl derivatives of turkesterone and, as far as the somewhat restricted range of analogues assessed permits, the activity pattern in the receptor assay is similar to that in the B_II bioassay with the activity decreasing with increasing acyl length from C₂ to C₄ and then increasing again with C₆ and C₁₀ acyl derivatives. The C₂₀ derivative has a very low activity. There is also good agreement between the K_i and EC₅₀ values for turkesterone 2-acetate. Thus, although these data reveal inconsistencies for turkesterone and 20E, they support the notion that steric bulk can be accommodated around C-11 of the ecdysteroid within the ligand binding pocket of EcR.

Since the receptor complex almost certainly consists of other protein components in addition to EcR and USP, which are unlikely to be present in the in vitro translated complexes, we include data (Table 6) on the comparison of the structure-activity relationships for the B_II bioassay and a cell-free receptor assay based on ecdysteroid receptor complexes extracted from B_II cells, where other endogenous transcription factors and binding proteins could be part of the extracted receptor complex. In general, there is reasonable agreement between the EC₅₀ and K_d values determined for most of the compounds. However, it is noticeable that the three 11α-hydroxy compounds included here (ajugasterone C, muristerone A and turkesterone) all have very low K_d/EC₅₀ ratios, as seen above for turkesterone in the comparison of the B_II bioassay and in vitro-expressed DmEcR/DmUSP.

Implications

Enhanced activity of 25-deoxy compounds: With the D. melanogaster B_II bioassay and in vitro DmEcR/DmUSP receptor assays, turkesterone shows considerably lower activity than 20E, although in other systems turkesterone is apparently more potent. Turkesterone was used in this study as a model compound, because it was the most readily available ecdysteroid possessing an 11α-hydroxyl group. However, to exploit the potential of 11α-derivatives it would be preferable to use higher potency analogues lacking the 25-hydroxyl group e.g ajugasterone C (EC₅₀ = 3.0 × 10⁻⁸M) or muristerone A (EC₅₀ = 2.2 × 10⁻⁸M), which should generate 11α-derivatives with ca. 100-fold greater activity than those listed in Table 5.

Future synthesis of 11β-acyl derivatives: It would be desirable to synthesise a parallel series of 11β-acyl derivatives in order to compare their activities to those of the 11α-acyl analogues. Realisation of this goal will be complicated by the absence of any known 11β-hydroxy ecdysteroids (Lafont et al., 2002) and the ready tendency of 11α-hydroxy ecdysteroids to dehydrate, generating 7,9(11)-dien-6-ones, under a variety of chemical conditions (Canonica et al., 1977; Qui and Nie, 1983; Bourne et al., 2002), making sequential oxidation and reduction of the 11-hydroxyl group difficult.

Relationship to other steroid hormones: The availability of hydrophobic space in the ligand-binding pocket in the region of C-11 of the steroid appears to be a common feature of steroid hormone receptors. 11β-Amidoalkoxyphenyl estradiols are potent antioestrogens (Nique et al., 1994). The hydrophobic pocket has been exploited to develop 11β-substituted 19-norsteroids as fluorescent steroid derivatives for the glucocorticoid and progesterone receptors (Teutsch et al., 1994). The antiprogesterone RU486 (mifepristone), used as an abortifacient, is an 11β-aryl-19-nor steroid (Rosen et al., 1995).

Application for synthesis of tagged ecdysteroids: The studies shown here reveal that there is considerable steric space in the ligand binding pocket of DmEcR extending out from C-11 of the ecdysteroid, as was predicted from the CoMFA models. This area would thus be a good candidate for the preparation of tagged ecdysteroids, for example the attachment of a fluorescent moiety for the generation of an alternative, non-radioactive receptor assay ligand. Currently, [³H]ponA is almost exclusively used as the ligand for receptor assays, but it is expensive and, owing to its very high specific activity (120 – 180 Ci/mmol), requires regular repurification. C-11 could also be a good location for an affinity labelling moiety as an alternative to the photoreactive endogenous Δ⁷-en-6-one (Schaltmann and Pongs, 1982) or an extended conjugated system (7,9[11]-dien-6-one; Bourne et al., 2002). For example, bromoacetate derivatives have proved effective electrophilic affinity agents for vitamin D binding protein (Swamy et al., 2000) and the human progesterone receptor (Holmes et al., 1981). Also, a successful photoaffinity label for human multidrug resistance protein has been based on the steroid agosterol A (Ren et al., 2001), which is structurally similar to ecdysteroids and possesses an 11α-hydroxyl group, on to which the azidophenyl photoaffinity label is attached. Further, it has been found that insect EcR proteins when expressed in mammalian cells and partnered by RXR have altered ligand specificity and affinity, such that 20E, the endogenous hormone in insect systems, is virtually inactive. However, muristerone A, possessing an 11α-hydroxyl group, is active, but micromolar concentrations are required. For gene switching it would be highly desirable to identify ecdysteroids with higher affinity than muristerone A. Production of 11α-derivatives may enhance affinity by providing closer contact to the ligand binding pocket.