Total synthesis and biological evaluation of C16 analogs of (-)-dictyostatin

The structure-activity relationship of the crucial C16 region of (-)-dictyostatin was established through total synthesis of analogs followed by detailed biological characterization. A versatile synthetic strategy was used to prepare milligram quantities of 16-normethyldictyostatin, 16-epi-dictyostatin, and the C16-normethyl-C15Z isomer. Along the way, a number of other E/Z isomers and epimers were prepared, and a novel lactone ring contraction to make iso-dictyostatins with 20-membered macrolactones (instead of 22-membered macrolactones) was discovered. The synthesis of 16-normethyl-15,16- dehydrodictyostatin is the first of any dictyostatin by a maximally convergent route in which three main fragments are assembled, coupled in back-to-back steps, and then processed through refunctionalization and macrolactonization. Cell-based and biochemical evaluations showed 16-normethyl-15,16- dehydrodictyostatin and 16-normethyldictyostatin to be the most potent of the new agents, only 2- and 5-fold less active than (-)-dictyostatin itself. This data and that from previously generated dictyostatin analogs are combined to produce a picture of the structure-activity relationships in this series of anticancer agents. © 2007 American Chemical Society

Synthesis and biological evaluation of (-)-16-normethyldictyostatin: A potent analogue of (-)-dictyostatin

(Chemical Equation Presented) (-)-16-Normethyldictyostatin has been made by total synthesis and is a potent antitumor agent in cells expressing wild-type tubulin and in one mutant cell line that is resistant to paclitaxel, but it is much less active than dictyostatin in another paclitaxel-resistant cell line where Val is substituted for Phe270. This provides strong evidence that the C16 methyl group of the dictyostatins is oriented toward Phe270 in the paclitaxel-binding site on β-tubulin. © 2005 American Chemical Society

Cell-based and biochemical structure-activity analyses of analogs of the microtubule stabilizer dictyostatin

Compounds that bind to microtubules (MTs) and alter their dynamics are highly sought as a result of the clinical success of paclitaxel and docetaxel. The naturally occurring compound (-)-dictyostatin binds to MTs, causes cell cycle arrest in G2/M at nanomolar concentrations, and retains antiproliferative activity in paclitaxel-resistant cell lines, making dictyostatin an attractive candidate for development as an antineoplastic agent. In this study, we examined a series of dictyostatin analogs to probe biological and biochemical structure-activity relationships. We used a high-content multiparameter fluorescence-based cellular assay for MT morphology, chromatin condensation, mitotic arrest, and cellular toxicity to identify regions of dictyostatin that were essential for biological activity. Four analogs (6-epi-dictyostatin, 7-epi-dictyostatin, 16-normethyldictyostatin, and 15Z,16-normethyldictyostatin) retained low nanomolar activity in the cell-based assay and were chosen for analyses with isolated tubulin. All four compounds were potent inducers of MT assembly. Equilibrium binding constant (K i) determinations using [14C]epothilone B, which has a 3-fold higher affinity for the taxoid binding site than paclitaxel, indicated that 6-epi-dictyostatin and 7-epi-dictyostatin displaced [14C] epothilone B with Ki values of 480 and 930 nM, respectively. 16-Normethyl-dictyostatin and 15Z,16-normethyldictyostatin had reduced affinity (Ki values of 4.55 and 4.47 μM, respectively), consistent with previous reports showing that C16-normethyldictyostatin loses potency in paclitaxel-resistant cell lines that have a Phe270-to-Val mutation in the taxoid binding site of β-tubulin. Finally, we developed a set of quantitative structure-activity relationship equations correlating structures with antiproliferative activity. The equations accurately predicted biological activity and will help in the design of future analogs. Copyright © 2008 The American Society for Pharmacology and Experimental Therapeutics

New antiestrogens from a library screen of homoallylic amides, allylic amides, and C-cyclopropylalkylamides

A new structural scaffold for antiestrogens was identified from the cell-based screening of a 67-member library of homoallylic amides, allylic amides, and C-cyclopropylalkylamides. Several derivatives had activity comparable to that of tamoxifen. A new structural scaffold for antiestrogens was identified from the cell-based screening of transcriptional regulation properties of a 67-member library of homoallylic amides, allylic amides, and C-cyclopropylalkylamides. C-Cyclopropylalkylamide 3a (O-ethyl-N-{2-[(1S*, 2R*)-2-{(R*)-[(diphenylphosphinoyl)amino](phenyl)methyl}cyclopropyl] ethyl}-N-[(4-methylphenyl)sulfonyl]carbamate) had antagonistic activity similar to that of tamoxifen and was further evaluated. Compound 3a inhibited estradiol-induced proliferation of the ER-positive MCF-7 cells but had no effect on ER-negative MDA-MB231 human breast cancer cells. Furthermore, high micromolar concentrations of 3a exhibited minimal cytotoxicity to the ER-negative line. The biological activities of the enantiomers of 3a did not differ from one another nor from that of racemic 3a. © 2004 Elsevier Ltd. All rights reserved

Synthesis and biological evaluation of (-)-dictyostatin and stereoisomers

Total syntheses of (-)-dictyostatin, 6,16-bis-epi-dictyostatin, 6,14,19-tris-epi-dictyostatin, and a number of other isomers and analogs are reported. Three main fragments-top, middle, and bottom-were first assembled and then joined by olefination or anionic addition reactions. After appending the two dienes at either end of the molecule, macrolactonization and deprotection completed the syntheses. The work proves both the relative and absolute configurations of (-)-dictyostatin. The compounds were evaluated by cell-based measurements of increased microtubule mass and antiproliferative activity, and in vitro tubulin polymerization assays as well as competitive assays with paclitaxel for its binding site on microtubules. These assays showed dictyostatin to be the most potent of the agents and further showed that the structural alterations caused from 20- to >1000-fold decreases in activity. © 2007 Elsevier Ltd. All rights reserved