Rapid Telomere Reduction in Cancer Cells Induced by G-Quadruplex-Targeting Copper Complexes

Telomere length determines the replicative capacity of mammalian cells. Successive telomere reduction to a critically short length can lead to cellular senescence that irreversibly prevents cells from further cell division. A series of Cu complexes has been designed as selective artificial nucleases that degrade G-quadruplex telomeric DNA and exhibit selective DNA binding affinity and cleavage reactivity toward G-quadruplex telomeric DNA over duplex DNA. In contrast to protein based nucleases that usually lack membrane permeability, significant cellular uptake and nuclear localization of these Cu complexes was observed. Rapid telomere reduction of cancer cells was also observed after only 1 day incubation, while the absence of DNA fragmentation indicates a low level of nonselective DNA cleavage. Robust telomere reduction by the designed Cu complexes is an S-phase specific event that is associated with increased formation of the G-quadruplex structure during DNA replication.