Abstract
Iron (Fe) is an essential element that plays a fundamental role in a wide range of cellular functions, including cellular proliferation, DNA synthesis, as well as DNA damage and repair. Because of these connections, iron has been strongly implicated in cancer development. Cancer cells frequently have changes in the expression of iron regulatory proteins. For example, cancer cells frequently upregulate transferrin (increasing uptake of iron) and down regulate ferroportin (decreasing efflux of intracellular iron). These changes increase the steady-state level of intracellular redox active iron, known as the labile iron pool (LIP). The LIP typically contains approximately 2% intracellular iron, which primarily exists as ferrous iron (Fe2+). The LIP can readily contribute to oxidative distress within the cell through Fe2+-dioxygen and Fenton chemistries, generating the highly reactive hydroxyl radical (HO•). Due to the reactive nature of the LIP, it can contribute to increased DNA damage. Mitochondrial dysfunction in cancer cells results in increased steady-state levels of hydrogen peroxide and superoxide along with other downstream reactive oxygen species. The increased presence of H2O2 and O2•− can increase the LIP, contributing to increased mitochondrial uptake of iron as well as genetic instability. Thus, iron metabolism and labile iron pools may play a central role connecting the genetic mutational theories of cancer to the metabolic theories of cancer.
Highlights
While not recognized as a traditional hallmark of cancer, increased iron availability is an integral feature of neoplastic disease
There is a large amount of data showing that tumors preferentially upregulate iron import pathways (i.e., TfR upregulation via c-Myc, EGFR, etc.) while preventing its export
The increased uptake of iron into both the cytosolic and mitochondrial compartments of cells may be contributing to increased utilization of Fe (e.g., Mfn-2/ISCU/Frataxin upregulation) and increased cellular proliferation
Summary
While not recognized as a traditional hallmark of cancer, increased iron availability is an integral feature of neoplastic disease. The iron in the labile iron pool (LIP) exists primarily in the ferrous, Fe2+, oxidation state [14]. Ferrous iron can oxidation of a wide range of biomolecules, similar to classical Fenton chemistry [4,6]. Simplified the network network for for intracellular intracellular iron iron regulation This model genetic and metabolic theories of cancer where the intracellular labile iron pool (LIP). Acts as a central genetic and metabolic theories of cancer where the intracellular labile iron pool (LIP) acts as a central hub in in the the genesis genesis of of cancer cancer thereby thereby linking linking iron iron metabolism metabolism to to traditional traditional hallmarks hallmarks of ofcancer
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