Paclitaxel (PTX) is a microtubule-stabilizing agent that is widely used in cancer chemotherapy. This structurally complex natural product acts by binding to β-tubulin in assembled microtubules. The 2'-hydroxyl group in the flexible side chain of PTX is an absolute requirement for activity, but its precise role in the drug-receptor interaction has not been specifically investigated. The contribution of the 2'-OH group to the affinity and tubulin-assembly efficacy of PTX has been evaluated through quantitative analysis of PTX derivatives possessing side chain deletions: 2'-deoxy-PTX, N-debenzoyl-2'-deoxy-PTX, and baccatin III. The affinity of 2'-deoxy-PTX for stabilized microtubules was more than 100-fold lower than that of PTX and only ~3-fold greater than the microtubule affinity of baccatin III. No microtubule binding activity was detected for the analogue N-debenzoyl-2'-deoxy-PTX. The tubulin-assembly efficacy of each ligand was consistent with the microtubule binding affinity, as was the trend in cytotoxicities. Molecular dynamics simulations revealed that the 2'-OH group of PTX can form a persistent hydrogen bond with D26 within the microtubule binding site. The absence of this interaction between 2'-deoxy-PTX and the receptor can account for the difference in binding free energy. Computational analyses also provide a possible explanation for why N-debenzoyl-2'-deoxy-PTX is inactive, in spite of the fact that it is essentially a substituted baccatin III. We propose that the hydrogen bonding interaction between the 2'-OH group and D26 is the most important stabilizing interaction that PTX forms with tubulin in the region of the C-13 side chain. We further hypothesize that the substituents at the 3'-position function to orient the 2'-OH group for a productive hydrogen bonding interaction with the protein.
Paclitaxel (n class="Chemical">PTX) is a microtubule-stabilizing agent that is widely used in cancer chemotherapy. This structurally complex natural product acts by binding to β-tubulin in assembled microtubules. The 2'-hydroxyl group in the flexible side chain of PTX is an absolute requirement for activity, but its precise role in the drug-receptor interaction has not been specifically investigated. The contribution of the 2'-OH group to the affinity and tubulin-assembly efficacy of PTX has been evaluated through quantitative analysis of PTX derivatives possessing side chain deletions: 2'-deoxy-PTX, N-debenzoyl-2'-deoxy-PTX, and baccatin III. The affinity of 2'-deoxy-PTX for stabilized microtubules was more than 100-fold lower than that of PTX and only ~3-fold greater than the microtubule affinity of baccatin III. No microtubule binding activity was detected for the analogue N-debenzoyl-2'-deoxy-PTX. The tubulin-assembly efficacy of each ligand was consistent with the microtubule binding affinity, as was the trend in cytotoxicities. Molecular dynamics simulations revealed that the 2'-OH group of PTX can form a persistent hydrogen bond with D26 within the microtubule binding site. The absence of this interaction between 2'-deoxy-PTX and the receptor can account for the difference in binding free energy. Computational analyses also provide a possible explanation for why N-debenzoyl-2'-deoxy-PTX is inactive, in spite of the fact that it is essentially a substituted baccatin III. We propose that the hydrogen bonding interaction between the 2'-OH group and D26 is the most important stabilizing interaction that PTX forms with tubulin in the region of the C-13 side chain. We further hypothesize that the substituents at the 3'-position function to orient the 2'-OH group for a productive hydrogen bonding interaction with the protein.
Authors: Malathi Hari; Frank Loganzo; Tami Annable; Xingzhi Tan; Sylvia Musto; Daniel B Morilla; James H Nettles; James P Snyder; Lee M Greenberger Journal: Mol Cancer Ther Date: 2006-02 Impact factor: 6.261
Authors: Rubén M Buey; Isabel Barasoain; Evelyn Jackson; Arndt Meyer; Paraskevi Giannakakou; Ian Paterson; Susan Mooberry; José M Andreu; J Fernando Díaz Journal: Chem Biol Date: 2005-12
Authors: Y Han; A G Chaudhary; M D Chordia; D L Sackett; B Perez-Ramirez; D G Kingston; S Bane Journal: Biochemistry Date: 1996-11-12 Impact factor: 3.162
Authors: J Jiménez-Barbero; A A Souto; M Abal; I Barasoain; J A Evangelio; A U Acuña; J M Andreu; F Amat-Guerri Journal: Bioorg Med Chem Date: 1998-10 Impact factor: 3.641
Authors: Elizabeth H Kellogg; Nisreen M A Hejab; Stuart Howes; Peter Northcote; John H Miller; J Fernando Díaz; Kenneth H Downing; Eva Nogales Journal: J Mol Biol Date: 2017-01-17 Impact factor: 5.469
Authors: V Pannu; P C G Rida; B Celik; R C Turaga; A Ogden; G Cantuaria; J Gopalakrishnan; R Aneja Journal: Cell Death Dis Date: 2014-11-20 Impact factor: 8.469