Abstract
Interference with telomerase and telomere maintenance is emerging as an attractive target for anticancer therapies. Ligand-induced stabilization of G-quadruplex formation by the telomeric DNA 3′-overhang inhibits telomerase from catalyzing telomeric DNA synthesis and from capping telomeric ends, making these ligands good candidates for chemotherapeutic purposes. BRACO-19 is one of the most effective and specific ligand for telomeric G4. It is shown here that BRACO-19 suppresses proliferation and reduces telomerase activity in human glioblastoma cells, paralleled by the displacement of telomerase from nuclear to cytoplasm. Meanwhile, BRACO-19 triggers extensive DNA damage response at telomere, which may result from uncapping and disassembly of telomeric T-loop structure, characterized by the formation of anaphase bridge and telomere fusion, as well as the release of telomere-binding protein from telomere. The resulting dysfunctional telomere ultimately provokes p53 and p21-mediated cell cycle arrest, apoptosis and senescence. Notably, normal primary astrocytes do not respond to the treatment of BRACO-19, suggesting the agent's good selectivity for cancer cells. These results reinforce the notion that G-quadruplex binding compounds can act as broad inhibitors of telomere-related processes and have potential as selective antineoplastic drugs for various tumors including malignant gliomas.
Highlights
Human telomeres which are located on the ends of chromosomes are composed of repetitive TTAGGG sequences and associated proteins
The telomerase inhibitory effects of BRACO-19 in U87 and U251 cells were investigated with the traditional Telomere repeat amplification protocol (TRAP) assay [5, 26,27,28]
This short-term effect cannot be explained by telomerase inhibition, which would lead to a gradual shortening of telomeres after a certain number of cell divisions
Summary
Human telomeres which are located on the ends of chromosomes are composed of repetitive TTAGGG sequences and associated proteins. They play important roles in protecting the ends of chromosomes from recombination, end-to-end fusions, or exonuclease action [1,2,3]. Telomeres in tumor cells are stably maintained in length and significantly shorter than normal cells. In approximately 85% of human tumors, the integrity of telomere is maintained by a specialized reverse transcriptase named telomerase [5]. In a small percentage of tumors, an alternate pathway for telomere length may be operational and involves recombination events [6]. Interference with telomerase and telomere maintenance represents an attractive strategy for anticancer therapy [7,8,9]
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