Iron Chelator VLX600 Inhibits Mitochondrial Respiration and Promotes Sensitization of Neuroblastoma Cells in Nutrition-Restricted Conditions

Simple Summary MYC proteins are essential regulators which could affect more than 15% of all genes through an interaction with other transcription factors. High-risk neuroblastoma associated with treatment failure is characterized by amplification of the MYCN proto-oncogene. Here, we show for the first time that the iron chelator VLX600 inhibits mitochondrial activity and induces cell death, regardless of MYCN status in neuroblastoma cells. Blocking glucose uptake enhances the effect of VLX600, indicating that targeting pathways or cellular activities related to energy supply/metabolism may help to find better therapeutic strategy for neuroblastoma. Neuroblastoma, the most common solid tumor in children, is characterized by amplification of the MYCN proto-oncogene, a high-risk aggressive clinical marker associated with treatment failure. MYCN plays an important role in cell growth, proliferation, metabolism, and chemoresistance. Here, we show for the first time that in neuroblastoma, iron chelator VLX600 inhibits mitochondrial respiration, decreases expression levels of MYCN/LMO1, and induces an efficient cell death regardless of MYCN status in both 2D and 3D culture conditions. Moreover, insufficient induction of autophagy was observed in cells treated with VLX600, which is essential as a protective response in the event of ATP synthesis disruption. Further inhibition of glucose uptake using DRB18, a pan-GLUT (glucose transporter) inhibitor, synergized the effect of VLX600 and no significant cell death was found in immortalized epithelial cells under this combination treatment. Our results demonstrate that inhibition of mitochondrial respiration by iron chelator VLX600 accompanied by autophagy deficiency promotes sensitivity of neuroblastoma cells in a nutrition-restricted microenvironment regardless of MYCN status, indicating that MYCN expression level is an essential clinical marker but might not be a necessary target for the treatment of neuroblastoma which warrants further investigation. VLX600 has been studied in Phase I clinical trials; combining VLX600 with conventional chemotherapy could be an innovative therapeutic strategy for neuroblastoma.

Automated summary

This study demonstrates for the first time that the iron chelator VLX600 inhibits mitochondrial activity and induces cell death regardless of MYCN status in neuroblastoma cells. Blocking glucose uptake enhances the effect of VLX600, suggesting potential therapeutic strategies for neuroblastoma targeting energy supply/metabolism pathways.