Paclitaxel is an anticancer agent isolated from the bark of the yew tree. It is classified as a microtubule-stabilizing agent and exerts cell killing effects by disrupting mitosis in dividing cells. Microtubules are made up of α- and β- tubulin heterodimers arranged head to tail and assembled to form a cylinder. Microtubules possess complex polymerization dynamics that are essential for movement of chromosomes and proper segregation of daughter cells during mitosis. Paclitaxel binds directly to the inner surface of β-subunits along the length of microtubules. Binding is thought to induce a conformational change in tubulin that increases its affinity for neighbouring molecules. At sufficiently high concentrations, paclitaxel can bind to β-tubulin in a one to one ratio and stimulate microtubule polymerization. At lower clinically relevant drug concentrations, paclitaxel stabilizes microtubules and prohibits further polymerization and depolymerization. Suppression of microtubule dynamics may prevent chromosomes from moving from the spindle poles to the metaphase plate slowing or preventing progression from metaphase to anaphase. Cells enter a state of mitotic arrest from which they may progress to one of several fates. The tetraploid cell may undergo unequal cell division producing aneuploid daughter cells. Alternatively, it may exit the cell cycle without undergoing cell division, a process termed mitotic slippage or adaptation. These cells may continue progressing through the cell cycle as tetraploid cells (Adaptation I), may exit G1 phase and undergo apoptosis or senescence (Adaption II), or may escape to G1 and undergo apoptosis during interphase (Adaptation III). Another possibility is cell death during mitotic arrest. Alternatively, mitotic catastrophe may occur causing cell death. Paclitaxel is susceptible to cellular drug resistance caused by drug efflux via a number of multidrug resistance-associated proteins.

Paclitaxel Pathway (old) References