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 H-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-FCHCHO, m-CFCHCHO, COMe(CH)CHO). The products were tested on a mouse lymphoma cell line pair, L5178 and its ABCB1-transfected multi-drug resistant counterpart, L5178, for their in vitro activity alone and in combination with doxorubicin, and for the ability to inhibit the ABCB1 transporter.

Enantioselective catalytic approach to the C23-C28 subunit of 24α-methyl steroids.

Enantioselective synthesis of C23-C28 subunit of campestane steroids based on catalytic methods is reported. The synthesis was started from (S)-2-isopropyl-4-nitrobutan-1-ol, which is easily accessible by the reaction between isovaleraldehyde and nitroethylene catalyzed by only 2% of (S)-trimethylsilyldiphenylprolinol. Removal of one "extra" carbon from the nitroalcohol was achieved by Ni-catalyzed hydrodecarboxylation of the redox-active ester intermediate.

Molecular rearrangements of poststerone derivative steroid core with formation of unique D-homostructures of pregnane and androstane series.

20R-Hydroxy short-chain ecdysteroids were synthesized by chemo- and stereoselective reduction of poststerone acetonide with L-Selectride or LiAlH. The same reaction with the excess of L- Selectride followed by the treatment of the reaction mixture with hydrochloric acid is accompanied by (8R)-13(14 → 8)abeo- rearrangements, which resulted in the contraction/expansion of C/D pregnane rings. The reaction of 20R-hydroxy poststerone analogs with (diethylamino)sulfur trifluoride (DAST) proceeds through intramolecular rearrangements and provides D-homo- or 13,14-seco- androstane structures.

Sonochemically assisted 2,3-dideoxygenation and skeletal rearrangement of ecdysteroid derivatives.

Sonochemical 2,3-dideoxygenation of ecdysteroids with the Δ -bond generation and activation of the C-C bonds of the steroid core in the poststerone derivatives, that causes the skeletal rearrangement have been carried out for the first time. Thus, the ultrasonically assisted reaction of 2,3-dimesyloxy derivatives of ecdysteroids with the NaI-Zn-DMF system gives rise to their 2,3-dideoxy-Δ-analogues with yields 70-92%. In the case of 2,3-dimesyloxypoststerone as the initial ecdysteroid substrate the reaction is accompanied by the activation of the allyl moiety and semipinacol rearrangement, resulting in the C-C bond migration with C/D rings contraction/expansion and providing novel short chain (8R)-13(14 → 8)-abeo-isomer.

Hydroxylation and epimerization of ecdysteroids in alkaline media: stereoselective synthesis of 9α-hydroxy-5α-ecdysteroids.

Autoxidation of diacetonides of 20-hydroxyecdysone and ponasterone A under treatment with excess of NaOH in methanol leads to the formation of 9α-hydroxy-5α-ecdysteroids previously not described. Their structures have been determined by detailed NMR analysis. Catalytic hydrogenation (Pd-C, MeOH-MeONa) of hydroxylated ecdysteroids affords the 7,8α-dihydro-9α-hydroxy-5α-ecdysteroids.

Hydrogenation of ecdysteroids.

Catalytic hydrogenation is extensively used in steroid chemistry. The interest in transformations to the steroid skeleton of ecdysteroids has been increasing in the past years. Essential interest in the chemistry of ecdysteroids is caused by the selective reduction of Δ7 bond with the formation of 7,8-dihydro analogues, because this process allows one to obtain modified structures with new biological activity.

Synthesis of 7,8α-dihydro-14α-deoxyecdysteroids.

A Pd-C-catalyzed hydrogenation in methanol and in the presence of sodium methylate is a simple, convenient and high yielding reduction method to convert the 7,14-dien-6-one ecdysteroids to their corresponding 7,8α-dihydro-14α-deoxyecdysteroids.