Syntheses and Bioactivities of Targeted and Conformationally Restrained Paclitaxel and Discodermolide Analogs

Yang, Chao

17 October 2008

Paclitaxel was isolated from the bark of <i>Taxus brevifolia</i> in the late 1960s. It exerts its biological effect by promoting tubulin polymerization and stabilizing the resulting microtubules. Paclitaxel has become one of the most important current drugs for the treatment of breast and ovarian cancers. Studies aimed at understanding the biologically active conformation of paclitaxel bound on β–tubulin are described. In this work, the synthesis of isotopically labeled taxol analogs is described and the REDOR studies of this compound complexed to tubulin agrees with the hypothesis that palictaxel adopts T-taxol conformation. Based on T-taxol conformation, macrocyclic analogs of taxol have been prepared and their biological activities were evaluated. The results show a direct evidence to support T-taxol conformation. (+) Discodermolide is a polyketide isolated from the Caribbean deep sea sponge <i>Discodermia dissoluta</i> in 1990. Similar to paclitaxel, discodermolide interacts with tubulin and stabilizes the microtubule <i>in vivo</i>. Studies aimed at understanding the biologically active conformation of discodermolide bound on β–tubulin are described. In this work, the synthesis of fluorescent labeled discodermolide analogs is described and their biological activities were evaluated. Synthetic approaches to fluorescent labeled and isotopically labeled discodermolide analogs discodermolide are also described. / Ph. D.

tubulin-binding conformation

macrocyclic taxoids

T-taxol conformation

discodermolide

Taxol

drug targeting

thio-taxol

Design, Syntheses and Biological Activities of Paclitaxel Analogs

Zhao, Jielu

03 May 2011

The conformation of paclitaxel in the bound state on the protein has been proposed to be the T-taxol conformation, and paclitaxel analogs constrained to the T-taxol conformation proved to be significantly more active than paclitaxel in both cytotoxicity and tubulin polymerization assays, thus validating the T-taxol conformation as the tubulin-binding conformation. In this work, eight compounds containing an aza-tricyclic moiety as a mimic of the baccatin core of paclitaxel have been designed and synthesized as water-soluble simplified paclitaxel analogs, among which 3.50-3.52 and 3.55 were conformationally constrained analogs designed to bind to the paclitaxel binding site of tubulin, based on their similarity to the T-taxol conformation. The open-chain analogs 3.41-3.43 and 3.57 and the bridged analogs 3.50-3.52 and 3.55 were evaluated for their antiproliferative activities against the A2780 cell lines. Analogs 3.50-3.52 and 3.55 which were designed to adopt the T-taxol conformation showed similar antiproliferative activities compared to their open-chain counterparts. They were all much less active than paclitaxel. In the second project, a series of paclitaxel analogs with various thio-containing linkers at C-2′ and C-7 positions were designed and synthesized in our lab. These analogs were attached to the surfaces of gold nanoparticles by CytImmune Sciences for the development of mutifunctional tumor-targeting agents. The native analogs and the gold bound analogs were evaluated for their antiproliferative activities against the A2780 cell line. All the compounds tested showed comparable or better activities than paclitaxel. Stability studies were performed for selected analogs in hydrolysis buffer, which showed that the analogs released paclitaxel in buffer over time. In the third project, the synthesis of a conformationally constrained paclitaxel analog which was designed to mimic the REDOR-taxol conformation was attempted. Two synthetic routes were tried and significant progress was made toward the synthesis of the conformationally constrained analog. However, both of the current synthetic routes failed to produce the key intermediate that would serve as the precursor for a ring-closing metathesis reaction to furnish the macrocyclic ring. / Ph. D.

T-taxol

tubulin

bioactive conformation

microtubules

thiolated paclitaxel

gold nanoparticles

conformationally constrained paclitaxel

simplified paclitaxel

Synthesis of Taxol™ Analogs as Conformational Probes

Metaferia, Belhu B.

31 July 2002

Taxol™, isolated from the bark of Taxus brevifolia in the late 1960s, and the semisynthetic analog Taxotere™ have proven clinical importance for the treatment of ovarian and breast cancer. Taxol™ exerts its biological effect by binding to polymerized tubulin and stabilizing the resulting microtubules. Studies aimed at understanding the biologically active conformation of taxol and its binding environment on β-tubulin are described. This knowledge is important because it could lead to the design of structurally less complicated drugs with better efficacy and better bioavailability. Moreover, the information can be extended to other natural products that possess microtubule-stabilizing properties similar to Taxol™. In this work, the synthesis of a triply labeled taxol analog is described as well as REDOR studies of this compound complexed to tubulin are in progress. Macrocyclic analogs of taxol have been prepared and their biological activities were evaluated. Chemical modeling of these analogs and their activities agrees with the hypothesis that Taxol™ adopts T-shaped conformation. Difficulties were encountered with the key ring-closing metathesis strategy, suggesting that a more flexible and efficient macrocyclization method will be needed to synthesize additional macrocyclic analogs. / Ph. D.

T-Taxol conformation

Tubulin

Taxol

Microtubules

Macrocyclic analogs

Anti-cancer agents

Ring-closing olefin metathesis

REDOR

ROESY

NAMFIS

Syntheses and Bioactivities of Targeted and Conformationally Restrained Taxol Analogs

Liu, Changhui

01 June 2004

Taxol (1) was first isolated from the bark of the Pacific yew about 35 years ago by Drs. Wall and Wani. Although its development as an anticancer agent was delayed by numerous reasons, including its scarcity and insolubility, the discovery of its tubulin-assembly activity and other factors motivated oncologists to overcome these problems. It has since become one of the most important current drugs for the treatment of several cancers, including breast and ovarian cancers. Like almost all anticancer drugs taxol does have some toxic side effects and many tumors also show significant resistance to therapy with taxol. Drug targeting studies aimed at improving its selectivity and efficacy is described. Two targeting methods, the estrogen receptor (ER) directed targeting and colloidal gold (cAu)directed targeting, were used in our research. In this dissertation, a series of estradiol-taxol conjugates (ETCs) were synthesized. They were active in four cytotoxicity assays and tubulin polymerization assay, but less active than taxol. One of them showed the desired selectivity for ER positive cancer cells. Recently, several studies have attempted to elucidate the bioactive binding conformation of taxol on microtubules. Three models have been proposed for this conformation. The T-taxol conformation was proposed by Dr. Snyder based on electron crystallographic density and molecular modeling. In this dessertation, a series of cyclopropyl-containing taxol analogs and macrocyclic taxol lactones were synthesized. The bioassay results showed they are less active than taxol. The molecular modeling studies suggested that the cyclopropyl-containing taxol analogs could not adopt the T-taxol conformation, which would result in the loss of bioactivities. It is an indirect evidence to support T-taxol conformation. As for macrocyclic taxol lactones, it is proposed that they would have a close contact between the ester moiety on the C-3' phenyl ring and Phe272 of the β-tubulin protein when they adopt T-taxol conformation. It will push the macrocyclics out of the binding pocket and lead to the lost of bioactivities. / Ph. D.

tubulin-binding conformation

thio-taxol

ER

estradiol

drug targeting

Taxol

cyclopropyl-taxol

T-taxol conformation

macrocyclic taxoids