Disruption of bioenergetics enhances the radio-sensitivity of patient-derived glioblastoma tumorspheres.

BACKGROUND

Despite available treatment approaches, including surgical resection along with chemotherapy and radiotherapy, glioblastoma (GBM), the most prevalent primary brain tumor, remains associated with a grim prognosis. Although radiotherapy is central to GBM treatment, its combination with bioenergetics regulators has not been validated in clinical practice. Here, we hypothesized that bioenergetics regulators can enhance the radio-sensitivity of GBM tumorspheres (TSs).

METHODS

Gene expression profiles of GBM patient-derived TSs were obtained through microarray and RNA-seq. In vitro treatment efficacy was assessed using clonogenic assay, 3D invasion assay, neurosphere formation assay, and flow cytometry. Protein expression was measured via western blot, and γH2AX foci were detected via immunofluorescence. In vivo efficacy was confirmed in an orthotopic xenograft model.

RESULTS

Based on radiation response-associated gene expression, GBM TSs were classified into high- or low-radioresistant groups. Among the five bioenergetics regulators, the pentose phosphate pathway inhibitor DHEA and the glycolysis inhibitor 2-DG notably enhanced the efficacy of ionizing radiation (IR) efficacy in vitro, reducing the survival fraction, stemness, and invasiveness in high- and low-radioresistant TSs. Combination with 2-DG further stimulated IR-induced DNA damage response and apoptosis in low-radioresistant GBM TSs. RNA-seq analysis revealed a downregulation of bioenergetics- and cell cycle-associated genes, whereas extracellular matrix- and cell adhesion-associated genes were enhanced by combined IR and 2-DG treatment. This therapeutic regimen extended survival and diminished tumor size in mouse xenograft models.

CONCLUSIONS

Our data suggest that combination with bioenergetics regulator 2-DG enhances the radio-sensitivity of GBM TSs, highlighting the clinical potential of this combined regimen.