Tumor cell-intrinsic HFE drives glioblastoma growth

Abstract

AbstractBackgroundGlioblastoma (GBM) tumor cells modulate expression of iron-associated genes to enhance iron uptake from the surrounding microenvironment, driving proliferation and tumor growth. The homeostatic iron regulator (HFE) gene, encoding the iron sensing HFE protein, is upregulated in GBM and correlates with poor survival outcomes. However, the molecular mechanisms underlying these observations remain unclear. Identification of pathways for targeting iron dependence in GBM tumors is therefore a critical area of investigation.MethodsWe interrogated the impact of cell-intrinsic Hfe expression on proliferation and tumor growth through genetic loss and gain of function approaches in syngeneic mouse glioma models. We determined the expression of iron-associated genes and their relationship with survival in GBM using public datasets and identified differentially expressed pathways in Hfe knockdown cells through Nanostring transcriptional profiling.ResultsLoss of Hfe induced apoptotic cell death in vitro and inhibited tumor growth in vivo while overexpression of Hfe accelerated both proliferation and tumor growth. Analysis of iron gene signatures in Hfe knockdown cells revealed alterations in the expression of several iron-associated genes, suggesting global disruption of intracellular iron homeostasis. Analyzing differentially expressed pathways further identified oxidative stress as the top pathway upregulated with Hfe loss. Enhanced 55Fe uptake and generation of reactive oxygen species (ROS) were found with Hfe knockdown, implicating toxic iron overload resulting in apoptotic cell death.ConclusionsCollectively, these findings identify a novel role for HFE in regulating iron homeostasis in GBM tumors and provide a potential avenue for future therapeutic development.Key PointsHFE is an iron sensor that is upregulated in GBM and negatively impacts survival.HFE overexpression drives proliferation and tumor growth in vivo.Loss of HFE increases production of reactive oxygen species and induces apoptosis, extending survival in vivo.Importance of StudyDysregulation of iron metabolism is an important feature of GBM contributing to tumor growth and negatively impacting survival. The identification of key iron regulators controlling this process is therefore important for therapeutic targeting. We identify HFE as an important regulator of iron homeostasis in GBM and suggest a role for sexual dimorphism in HFE-mediated tumor iron regulation that ultimately results in differential survival outcomes. Our findings demonstrate that HFE drives tumor cell proliferation and survival in GBM and may be a viable target for modulating tumor iron flux and inducing apoptosis in tumor cells.