In vitro adjuvant antitumor activity of various classes of semi-synthetic poststerone derivatives.

Various classes of semi-synthetic analogs of poststerone, the product of oxidative cleavage of the C20-C22 bond in the side chain of the phytoecdysteroid 20-hydroxyecdysone, were synthesized. The analogs were obtained by reductive transformations using L-Selectride and H2-Pd/C, by molecular abeo-rearrangements using the DAST reagent or ultrasonic treatment in the NaI-Zn-DMF system, and by acid-catalyzed reactions of poststerone derivatives with various aldehydes (o-FC6H4CHO, m-CF3C6H4CHO, CO2Me(CH2)8CHO). The products were tested on a mouse lymphoma cell line pair, L5178 and its ABCB1-transfected multi-drug resistant counterpart, L5178MDR, for their in vitro activity alone and in combination with doxorubicin, and for the ability to inhibit the ABCB1 transporter. Among the tested compounds, new 2,3-dioxolane derivatives of the pregnane ecdysteroid were found to have a pronounced chemosensitizing activity towards doxorubicin and could be considered as promising candidates for further structure optimization for the development of effective chemosensitizing agents.

1H and 13C NMR investigation of 20-hydroxyecdysone dioxolane derivatives, a novel group of MDR modulator agents.

The synthesis, structure elucidation and the complete (1)H and (13)C signal assignment of a series of dioxolane derivatives of 20-hydroxyecdysone, synthesized as novel modulators of multidrug resistance, are presented. The structures and NMR signal assignment were established by comprehensive one-dimensional and two-dimensional NMR spectroscopy supported by mass spectrometry.

Design and studies of novel polyoxysterol-based porphyrin conjugates.

New types of steroid-porphyrin conjugates derived from 20-hydroxyecdysone (20E) and 24-epibrassinolide (EBl) were synthesized. An exceptional regioselectivity in the reaction of both steroids with porphyrin boronic acids was found to give side-chain-conjugated boronic esters as sole products. UV-Vis-, fluorescence and NMR spectroscopy yielded similar data for all the studied compounds confirming the solvent driven supramolecular assembly with formation of J-aggregates. CD measurements of water diluted solutions showed a clear difference between 20E and EBl conjugates. The latter showed a strong supramolecular chirality, whereas 20E J-aggregates did not.

Synthesis of ponasterone A derivatives with various steroid skeleton moieties and evaluation of their binding to the ecdysone receptor of Kc cells.

A series of ponasterone A (PNA) derivatives with various steroid moieties were synthesized to measure their binding activity to the ecdysone receptors of Drosophila Kc cells. The activity of compounds was evaluated by determining the concentration required to give the 50% inhibition (IC(50) in M) of the incorporation of [(3)H]PNA to Drosophila Kc cells. Compounds with no functional groups such as OH and CO group in the steroid skeleton moiety were inactive. By the introduction of functional groups such as the OH and the CO group in the steroidal structure, these compounds became active. Some compounds containing the A/B-trans ring fusion, which is different from that (A/B-cis) of ecdysteroids were also active. The oxidation of CH(2) at 6-position to CO, enhanced the activity 19 times, but the activity was erased by the reduction of oxo to OH group at 6-position. The activity was enhanced about 250 times by the conversion of A/B ring configuration from trans [(20R,22R)-2beta,3beta,20,22-tetrahydroxy-5alpha-cholestan-6-one: pIC(50)=4.84] to cis [(20R,22R)-2beta,3beta,20,22-tetrahydroxy-5beta-cholestan-6-one: pIC(50)=7.23]. The latter cis-type compound which is the most potent among compounds synthesized in this study was equipotent to the natural molting hormone, 20-hydroxyecdysone, even though it is 1/50 of PNA.

C-25 epimeric 26-haloponasterone A: synthesis, absolute configuration and moulting activity.

A convenient synthesis of inokosterone has been accomplished. Inokosterone exists as two C-25 epimers, which could be separated from each other through their diacetonide derivatives. The absolute configuration of these compounds was determined. Two C-25 epimers of 26-chloroponasterone A were synthesized from the respective C-25 epimeric inokosterone. Two epimeric 26-bromo and 26-iodoponasterone A compounds were also synthesized. Moulting activity of these compounds was evaluated using the Musca bioassay, and it was found that the (25S)-26-halo analogues were more active than the corresponding (25R)-26-halo analogues. Among the 25S series, an increase in activity with an increase in size of the halogen atom was observed, indicating that the steric factor was more important than the electronic factor in binding of these ecdysteroid analogues to the receptor. On the other hand, a decrease in activity with an increase in size of the halogen atom was noted in the 25R series, suggesting that the steric factor was less important than the electronic factor. The results indicated that the configuration at C-25 and the substituent at C-26 have significant influences on the interaction of ecdysteroids with their receptor.

Stereoselective synthesis of (22R)- and (22S)-castasterone/ponasterone A hybrid compounds and evaluation of their molting hormone activity.

Two stereoisomers of a castasterone/ponasterone A hybrid compound, the (20R,22R) and (20R,22S)-isomers of 2alpha,3alpha,20,22-tetrahydroxy-5alpha-cholestan-6-one, were synthesized stereoselectively and their binding activity to the ecdysteroid receptor was determined. From the concentration-response curve for the inhibition of the incorporation of tritiated ponasterone A into ecdysteroid receptor containing insect cells, the concentration (IC50) required to inhibit 50% of the incorporation of radioactivity into cells was evaluated. The IC50 values of the (22R)- and (22S)-isomers were determined to be 0.30 and 38.9 microM against Kc cells, respectively, indicating that the (22R)-isomer is about 100 times more potent than the corresponding (22S)-isomer. IC50 values of these compounds against lepidopteran Sf-9 cells were determined to be 0.36 and 12.9 microM, respectively. The molting hormonal effect was examined in a Chilo suppressalis integument system and the 50% effective concentration for the stimulation of N-acetylglucosamine incorporation into the cultured integument was determined to be 2.7 microM for the (22R)-isomer, while the (22S)-isomer was inactive. On the other hand, both isomers did not show brassinolide-like activity in the rice lamina inclination assay.

Synthesis and biological activities of turkesterone 11alpha-acyl derivatives.

Turkesterone is a phytoecdysteroid possessing an 11alpha-hydroxyl group. It is an analogue of the insect steroid hormone 20-hydroxyecdysone. Previous ecdysteroid QSAR and molecular modelling studies predicted that the cavity of the ligand binding domain of the ecdysteroid receptor would possess space in the vicinity of C-11/C-12 of the ecdysteroid. We report the regioselective synthesis of a series of turkesterone 11alpha-acyl derivatives in order to explore this possibility. The structures of the analogues have been unambiguously determined by spectroscopic means (NMR and low-resolution mass spectrometry). Purity was verified by HPLC. Biological activities have been determined in Drosophila melanogaster B(II) cell-based bioassay for ecdysteroid agonists and in an in vitro radioligand-displacement assay using bacterially-expressed D. melanogaster EcR/USP receptor proteins. The 11alpha-acyl derivatives do retain a significant amount of biological activity relative to the parent ecdysteroid. Further, although activity initially drops with the extension of the acyl chain length (C2 to C4), it then increases (C6 to C10), before decreasing again (C14 and C20). The implications of these findings for the interaction of ecdysteroids with the ecdysteroid receptor and potential applications in the generation of affinity-labelled and fluorescently-tagged ecdysteroids are discussed.

Photochemical transformation of 20-hydroxyecdysone: production of monomeric and dimeric ecdysteroid analogues.

Structural modification of 20-hydroxyecdysone (20E) based on photochemical transformation yielded dimeric ecdysteroid 7alphaH,7'alphaH-bis-[(20R,22R)-2beta,3beta,20,22,25-pentahydroxy-5beta-cholest-8(14)-en-6-one-7-yl] as a main product. Its structure was determined by detailed NMR analysis. Furthermore, two new monomeric analogues: 14-epi-20-hydroxyecdysone and 14-deoxy-14,18-cyclo-20-hydroxyecdysone were identified in addition to the earlier described 14-deoxy and 14-hydroperoxy derivatives of 20E. Formation of the specific and so far unique ecdysteroid dimer has not been observed in earlier photo-transformation studies. The transformed dimeric analogue of 20-hydroxyecdysone retained the high agonistic activity on the ecdysone receptor in the B(II)-bioassay compared with the original 20E.

Affinity labelling of a partially purified ecdysteroid receptor with a bromoacetylated 20-OH-ecdysone derivative.

The novel bromoacetyl ecdysteroid IV, (20R,22R)-2 beta,3 beta,14 alpha,20,22,25 xi-hexahydroxy-26-(3- bromoacetoxypropyl)-5 beta-cholest-7-en-6-one, BAEIV, has been synthesized by extending the side chain on C26 of 20-OH-ecdysone. BAEIV meets all the requirements for an affinity-labelling reagent. It reacts with the partially purified ecdysteroid receptors of Drosophila melanogaster rapidly and almost quantitatively. Reactions require only micromolar concentrations of BAEIV. The rate of the affinity-labelling reaction is determined by the association of BAEIV with the ecdysteroid receptor. The value of the apparent reaction rate constant is very similar to that of the association rate constant for the binding of 20-OH-ecdysone to the ecdysteroid receptor. Product analysis of the reaction of [14C]BAEIV with the ecdysteroid receptor revealed two labelled peptides having molecular masses 150 kDa and 90 kDa. The smaller peptide is possibly a proteolytic fragment of the larger peptide. The identification of a 150-kDa peptide by chemical affinity labelling of the ecdysteroid receptor agrees with previously reported photoaffinity-labelling results from our laboratory. The results also demonstrate that the ecdysteroid receptor of D. melanogaster has a molecular mass higher than all other vertebrate steroid hormone receptors studied so far.

26-[125I]iodoponasterone A is a potent ecdysone and a sensitive radioligand for ecdysone receptors.

The effects of ecdysone, the steroid molting hormone of arthropods, are of considerable interest both to insect physiologists and to those studying steroid-regulated gene expression. Yet progress in understanding ecdysone receptors has been inhibited by the lack of a suitable highly radioactive hormone analog with high affinity for the receptor. Here we report that the synthetic ecdysteroid 26-iodoponasterone A is one of the most active ecdysones known, inducing half-maximal morphological transformation in Drosophila Kc167 cells when present at 0.5 nM. 26-[125I]Iodoponasterone A can be prepared at a specific activity of 2175 Ci/mmol (1 Ci = 37 GBq) by reaction of the precursor 26-mesylinokosterone with carrier-free Na125I. The radiolabeled material binds to Kc167 cell ecdysone receptors specifically and with affinity (Kd ca. 3.8 X 10(-10) M). Thus, 26-[125I]iodoponasterone A appears to be a superior radioligand for ecdysone receptors on grounds both of affinity and of specific activity. Its ready availability should greatly facilitate studies of these receptors.

Characterization and partial purification of the Drosophila Kc cell ecdysteroid receptor.

The molting hormones of insects, the ecdysteroids, are steroids whose action is mediated by an intracellular receptor. The Kc cell line of Drosophila melanogaster possesses ecdysteroid receptors and exhibits characteristic, receptor-dependent morphological and biochemical responses to the application of ecdysteroids. This paper describes the interaction of muristerone A (2 beta, 3 beta, 5 beta, 11 alpha, 14 alpha(20R,22R)- heptahydroxycholest-7-en-6-one), a phytoecdysteroid, with the Kc cell ecdysteroid receptor. Muristerone A-receptor complexes are not as sensitive to dissociation in high salt buffers as other ecdysteroid-receptor complexes we have examined. This has enabled us to use [3H]muristerone A to follow the Kc cell ecdysteroid receptor during heparin-agarose, DNA-cellulose, and hydroxylapatite chromatography, as well as gel filtration and ion exchange high pressure liquid chromatography. The Drosophila Kc cell ecdysteroid receptor has a Stokes radius of 4.6 nm, a frictional coefficient of 1.4, and a molecular weight of 120,000. A procedure is presented that results in a 750-fold enrichment of the receptor.

Enzymatic and chemical synthesis of 3-dehydroecdysterone, a metabolite of the moulting hormone of insects.

3-Dehydroecdysterone, a less polar metabolite of ecdysterone, was synthesized in vitro using either an enzyme (edcysone oxidase, EC 1.1.3.16) or the chemical catalyst platinum. 3-Dehydroecdysterone was purified and characterized by its chromatographic behaviour, its staining properties and by UV, IR, NMR and mass spectroscopy. The compound is 1/15 as active as ecdysone in the Calliphora moulting hormone bioassay. Its biological relevance is discussed.