Abstract

Diaminothiazoles are novel cytotoxic compounds that have shown efficacy toward different cancer cell lines. They show potent antimitotic and antiangiogenic activity upon binding to the colchicine-binding site of tubulin. However, the mechanism of action of diaminothiazoles at the molecular level is not known. Here, we show a reversible binding to tubulin with a fast conformational change that allows the lead diaminothiazole DAT1 [4-amino-5-benzoyl-2-(4-methoxy phenyl amino)thiazole] to cause a reversible mitotic block. DAT1 also suppresses microtubule dynamic instability at much lower concentration than its IC(50) value in cancer cells. Both growth and shortening events were reduced by DAT1 in a concentration-dependent way. Colchicine, the long-studied tubulin-binding drug, has previously failed in the treatment of cancer due to its toxicity, even though it generates a strong apoptotic response. The toxicity is attributable to its slow removal from the cell due to irreversible tubulin binding caused by a slow conformational change. DAT1 binds to tubulin at an optimal pH lower than colchicine. Tubulin conformational studies showed that the binding environments of DAT1 and colchicine are different. Molecular dynamic simulations showed a difference in the number of H-bonding interactions that accounts for the different pH optima. This study gives an insight of the action of compounds targeting tubulin's colchicine-binding site, as many such compounds have entered into clinical trials recently.

Highlights

  • A major role of microtubules is to form the spindle leading to segregation of chromosomes during mitotic cell division

  • Because the density of microtubules is very high within the mitotic spindle, we examined the turnover of interphase microtubules and focused our analysis on microtubules extending to the cell periphery

  • DAT1 was added to the culture medium at 2 different concentrations: 80 nmol/L, which was much less than the average IC50 of DAT1 in cancer cells (0.3 mmol/L; ref. 14) and at 1.6 mmol/L, a concentration 5-fold higher than the IC50

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Summary

Introduction

A major role of microtubules is to form the spindle leading to segregation of chromosomes during mitotic cell division. Because of this critical function, microtubules have become a popular target to stop cancer cell proliferation and many microtubule-targeting compounds have shown high capability to kill and arrest the progression of tumors [1]. Authors' Affiliations: 1Division of Cancer Research, 2Distributed Information Sub-Centre, Rajiv Gandhi Centre for Biotechnology; 3Department of Chemistry, University of Kerala, Trivandrum, India; and 4Department of Biological Sciences, Lehigh University, Bethlehem, Pennsylvania. Current address for K.J. Sreedevi: IIST, Trivandrum, Kerala, India; and current address for X.L. Louis: CCARM, Manitoba, Canada, R2H2A6

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