Improved Dose-Response Relationship of (+)-Discodermolide-Taxol Hybrid Congeners

Overview

Journal J Nat Prod

Date 2018 Mar 10

PMID 29522336

Citations 2

Authors

Celine Nadaradjane

Chia-Ping Huang Yang

Alicia Rodriguez-Gabin

Kenny Ye

Keizo Sugasawa

Onur Atasoylu

Amos B Smith 3rd

Susan Band Horwitz

Hayley M McDaid

Affiliations

Soon will be listed here.

Abstract

(+)-Discodermolide is a microtubule-stabilizing agent with potential for the treatment of taxol-refractory malignancies. (+)-Discodermolide congeners containing the C-3'-phenyl side chain of taxol (paclitaxel) were synthesized based on computational docking models predicting this moiety would fill an aromatic pocket of β-tubulin insufficiently occupied by (+)-discodermolide, thereby conferring improved ligand-target interaction. It was recently demonstrated, however, that the C-3'-phenyl side chain occupied a different space, instead extending toward the M-loop of β-tubulin, where it induced a helical conformation, hypothesized to improve lateral contacts between adjacent microtubule protofilaments. This insight led us to evaluate the biological activity of hybrid congeners using a panel of genetically diverse cancer cell lines. Hybrid molecules retained the same tubulin-polymerizing profile as (+)-discodermolide. Since (+)-discodermolide is a potent inducer of accelerated senescence, a fate that contributes to drug resistance, congeners were also screened for senescence induction. Flow cytometric and transcriptional analysis revealed that the hybrids largely retained the senescence-inducing properties of (+)-discodermolide. In taxol-sensitive cell models, the congeners had improved dose-response parameters relative to (+)-discodermolide and, in some cases, were superior to taxol. However, in cells susceptible to senescence, E increased without concomitant improvements in EC such that overall dose-response profiles resembled that of (+)-discodermolide.

Citing Articles

Taccalonolide C-6 Analogues, Including Paclitaxel Hybrids, Demonstrate Improved Microtubule Polymerizing Activities.

Risinger A, Hastings S, Du L J Nat Prod. 2021; 84(6):1799-1805.

PMID: 34110822 PMC: 8656239. DOI: 10.1021/acs.jnatprod.1c00211.

Structural Refinement of the Tubulin Ligand (+)-Discodermolide to Attenuate Chemotherapy-Mediated Senescence.

Guo B, Rodriguez-Gabin A, Prota A, Muhlethaler T, Zhang N, Ye K Mol Pharmacol. 2020; 98(2):156-167.

PMID: 32591477 PMC: 7362599. DOI: 10.1124/mol.119.117457.

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