Aptamer-guided acridine derivatives for cervical cancer

Abstract

DNA aptamers represent a way to target cancer cells at a molecular level and continue to be developed with a view to improve treatment and imaging in cancer medicine. AT11-L0, derived from the DNA sequence AT11, forms a single major parallel G-quadruplex (G4) conformation and exhibits an anti-proliferative activity similar to that of AT11 and AS1411 aptamers. On the other side, acridine orange derivatives represent a valuable class of G4 ligands. Herein, we evaluate AT11-L0 G4 as a supramolecular carrier for the delivery of acridine ligands C₃, C₅ and C₈ to HeLa cancer cells. The CD titrations suggest no changes in the chiroptical signal upon addition of an excess of ligands maintaining the parallel G4 topology and C₈ stabilizes the structure for more than 20 °C. All the ligands exhibit high affinity (micromolar range) towards AT11-L0 G4, and the respective complexes against nucleolin (nanomolar range) suggesting that the ligands do not negatively affect the recognition of the nucleolin by AT11-L0 G4. NMR studies showed that AT11-L0 forms a G4 containing four G-tetrad layers. Ligand C₈ binds AT11-L0 G4 through π–π stacking of the acridine moiety onto the top-tetrad with the involvement of additional interactions with the ligand's side chain and iodobenzene ring. In vitro, the complexes lowered the ligand's cytotoxicity towards non-malignant cells but have a weak inhibitory effect in HeLa cancer cells, except for the AT11-L0-C₅ complex. All complexes are efficiently internalized into nucleolin-positive HeLa cells. Overall, these results suggest that AT11-L0 can act as an aptamer by targeting nucleolin and a delivery system of cytotoxic ligands for cervical cancer.