Abstract
Ferroptosis, a recently discovered form of iron-dependent cell death, requires an increased level of lipid-reactive oxygen species (ROS). Ferritinophagy, a ferritin degradation pathway, depends on a selective autophagic cargo receptor (NCOA4). By screening various types of natural compounds, formosanin C (FC) was identified as a novel ferroptosis inducer, characterized by attenuations of FC-induced viability inhibition and lipid ROS formation in the presence of ferroptosis inhibitor. FC also induced autophagic flux, evidenced by preventing autophagic marker LC3-II degradation and increasing yellow LC3 puncta in tandem fluorescent-tagged LC3 (mRFP-GFP) reporter plasmid (ptfLC3) transfected cells when combined with autophagic flux inhibitor. It is noteworthy that FC-induced ferroptosis and autophagic flux were stronger in HepG2 cells expressing higher NCOA4 and lower ferritin heavy chain 1 (FTH1) levels, agreeing with the results of gene expression analysis using CTRP and PRISM, indicating that FTH1 expression level exhibited a significant negative correlation with the sensitivity of the cells to a ferroptosis inducer. Confocal and electron microscopy confirmed the pronounced involvement of ferritinophagy in FC-induced ferroptosis in the cells with elevated NCOA4. Since ferroptosis is a non-apoptotic form of cell death, our data suggest FC has chemotherapeutic potential against apoptosis-resistant HCC with a higher NCOA4 expression via ferritinophagy.
Highlights
Iron is an element that is critical for cell proliferation and growth
To identify natural compounds that have the potential to induce ferroptosis, human Hepatocellular carcinoma (HCC) HepG2 cells were treated with different kinds of phytochemicals for evaluating the viability of the cells
To determine if ferroptosis was involved in the formosanin C (FC)-induced viability inhibition, both HCC Hep3B and HepG2 cells were co-treated with ferroptosis inhibitor
Summary
Iron is an element that is critical for cell proliferation and growth. Besides these effects, iron creates reactive oxygen species (ROS) by participating in the Fenton reaction. Cellular iron metabolism comprises three major processes: iron uptake, storage, and export, which depend on three major proteins: transferrin receptor (TFRC), ferritin, and ferroportin (FPN), respectively. Several studies revealed that iron is highly demanded by cancer cells, as it facilitates the transformation and metastasis of tumor cells [1]. Ferroptosis is characterized by the iron-dependent accumulation of lipid ROS. Inhibition of cystine-glutamate antiporter (system Xc - ) causes the depletion of glutathione, especially glutathione
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