Abstract
Glioblastoma multiforme (GBM) is the most common form of brain tumor with a poor prognosis and resistance to radiotherapy. Recent evidence suggests that glioma-initiating cells play a central role in radioresistance through DNA damage checkpoint activation and enhanced DNA repair. To investigate this in more detail, we compared the DNA damage response in nontumor forming neural progenitor cells (NPC) and glioma-initiating cells isolated from GBM patient specimens. As observed for GBM tumors, initial characterization showed that glioma-initiating cells have long-term self-renewal capacity. They express markers identical to NPCs and have the ability to form tumors in an animal model. In addition, these cells are radioresistant to varying degrees, which could not be explained by enhanced nonhomologous end joining (NHEJ). Indeed, NHEJ in glioma-initiating cells was equivalent, or in some cases reduced, as compared with NPCs. However, there was evidence for more efficient homologous recombination repair in glioma-initiating cells. We did not observe a prolonged cell cycle nor enhanced basal activation of checkpoint proteins as reported previously. Rather, cell-cycle defects in the G(1)-S and S-phase checkpoints were observed by determining entry into S-phase and radioresistant DNA synthesis following irradiation. These data suggest that homologous recombination and cell-cycle checkpoint abnormalities may contribute to the radioresistance of glioma-initiating cells and that both processes may be suitable targets for therapy.
Highlights
Gliomas are the most common adult brain cancers, comprising 80% of diagnosed cases [1]
We first examined whether glioma-initiating cells had stem cell markers and self-renewal capacity comparable with neural progenitor cells (NPC)
The profile of stem cell markers differed between glioma-initiating cells cultures, but U251 and L1b showed near identical marker expression to NPCs (Supplementary Fig. S1A)
Summary
Gliomas are the most common adult brain cancers, comprising 80% of diagnosed cases [1]. Anaplastic astrocytoma (grade III) and glioblastoma multiforme (GBM; grade IV) tumors are highly lethal [1]. GBM are resistant to conventional treatment, leading to recurrence of brain tumors. 3), can survive exogenous damage, such as the lethal double strand breaks (DSB), to repopulate tumor cells following treatment. DSBs are highly detrimental to the structural integrity of chromosomes. To counteract this damage, normal and Authors' Affiliations: 1Queensland Institute of Medical Research; 2University of Queensland Centre for Clinical Research, Royal Brisbane Hospital Campus, Herston; 3University of Queensland, Diamantina Institute, Level 4, Princess Alexandra Hospital, Woollongabba; and 4Briz Brain and Spine, Level 10, The Wesley Hospital, Chasely Street, Auchenflower, Queensland, Australia
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