Abstract EN:

The key fibre components of the cytoskeleton, microtubules, are formed in vivo by the longitudinal assembly of 13 protofilaments via the addition (polymerisation) of heterodimers of α- and β- subunits of tubulin. They are hollow, tubular fibres whereby dynamic equilibrium is crucial for mitosis and cell division. The perturbation or arrest of their assembly/disassembly leads to cell apoptosis. During the course of this thesis, we were interested in the discovery of new, simple compounds via a fragment-based approach, that are similar to more complex, natural products such as Taxol®. These compounds stabilise the microtubules by inhibition of their disassembly. To realise our aim, we have initially synthesised a collection of different carboxylic acids and secondary amines, the fragments derived form epothilone, eleutherobin and other natural heterocycles that were used to build the libraries of amides. In order to evaluate the biological activity of the amide libraries, we have adopted the microtubule disassembly-based screening that allowed rapid identification of the most active library. Several deconvolutions led us to consequently identify the chemical structures of components being responsible for the stabilisation of microtubules. The observation of the synergistic effect between two active molecules led us to improve their chemical structures and to obtain the ligands with enhanced biological activity. In parallel to this work, we have focused on the first photoaffinity labeling studies of zinc-induced tubulin sheets that could potentially allow for the localisation of the taxoids binding site on microtubules. The preliminary results of the photoaffinity labeling of zinc-induced tubulin sheets and microtubules in the cylindrical form with [3H] TaxAPU, the Taxotere® photoanalogue, have showed that the α- and β-subunits of tubulin are labeled in both these forms in approximately the same ratio 30/70.