G-quadruplex structures are an attractive target for the development of anticancer drugs, as their formation in human telomere induces a DNA damage response followed by apoptosis in cancer cells. However, the development of new anticancer drugs by means of structural-based drug design is hampered by a lack of accurate information on the exact G-quadruplex conformation adopted by the human telomeric DNA under physiological conditions. Several groups reported that, in a molecular crowded, cell-like environment, simulated by polyethylene glycol (PEG), the human telomeric DNA adopts the parallel G-quadruplex conformation. These studies have suggested that 40% (w/v) PEG concentration induces complete structural conversion from the other known human telomeric G-quadruplex conformations to the parallel G-quadruplex, thus simplifying the high structural polymorphism existing in the absence of PEG. In this study, we demonstrate that the structural conversion to the parallel G-quadruplex is not a complete reaction at physiological temperature. We report a complete kinetic and thermodynamic characterization of the conformational transitions involving the (TTAGGG)(4)TT and (TTAGGG)(8)TT human telomeric DNA sequences in K(+) solution containing PEG. Our data show that the hybrid-type and parallel conformations coexist at equilibrium in the presence of PEG at physiological temperature and the degree of the quadruplex interconversion depends on the PEG molecular weight. Further, we find that telomeric DNA folds in the parallel quadruplex in the seconds time scale, a much larger time scale than the one reported for the hybrid quadruplex folding (~ms). The whole of our data allow us to predict the relative amount of each G-quadruplex conformation as a function of temperature and time. The effect of other crowding agents like Ficoll 400 and glycerol on the quadruplex interconversion has been also explored.
© 2012 American Chemical Society