Rotaxanating Metallo-supramolecular Nano-cylinder Helicates to Switch DNA Junction Binding.
Catherine A J HooperLucia CardoJames S CraigLazaros MelidisAditya GaraiRoss T EganViktoriia SadovnikovaFlorian BurkertLouise MaleNikolas J HodgesDouglas F BrowningRoselyne RosasFengbo LiuFillipe V RochaMauro A LimaSi-Min LiuDavid BardelangMichael J HannonPublished in: Journal of the American Chemical Society (2020)
A class of rotaxane is created, not by encapsulating a conventional linear thread, but rather by wrapping a large cucurbit[10]uril macrocycle about a three-dimensional, cylindrical, nanosized, self-assembled supramolecular helicate as the axle. The resulting pseudo-rotaxane is readily converted into a proper interlocked rotaxane by adding branch points to the helicate strands that form the surface of the cylinder (like branches and roots on a tree trunk). The supramolecular cylinder that forms the axle is itself a member of a unique and remarkable class of helicate metallo-drugs that bind Y-shaped DNA junction structures and induce cell death. While pseudo-rotaxanation does not modify the DNA-binding properties, proper, mechanically-interlocked rotaxanation transforms the DNA-binding and biological activity of the cylinder. The ability of the cylinder to de-thread from the rotaxane (and thus to bind DNA junction structures) is controlled by the extent of branching: fully-branched cylinders are locked inside the cucurbit[10]uril macrocycle, while cylinders with incomplete branch points can de-thread from the rotaxane in response to competitor guests. The number of branch points can thus afford kinetic control over the drug de-threading and release.