Project description:Therapeutic Perturbation of Liver and Bile Duct Cancer through Targeted Inhibition of FSP1 and GCS Induced Ferroptosis

Project description:Background/Objectives: Ferroptosis, an iron-dependent form of cell death, shows promise as a target for therapy-resistant cancers that exhibit increased iron metabolism. Ferroptosis is primarily characterised by lipid peroxidation within cell membranes. However, many cancers evade ferroptosis by upregulation of specialised ferroptosis defence mechanisms. This study investigates ferroptosis susceptibility in Tuberous Sclerosis Complex (TSC) cell models, and ovarian and breast cancer cell lines to identify ferroptosis resistance mechanisms and therapeutic targets. Methods: We assessed ferroptosis susceptibility using the ferroptosis inducers, RSL3 and erastin. We explored ferroptosis resistance genes using inhibitors of NRF2 (ML385) and FSP1 (iFSP1). RNA-sequencing was conducted to identify dysregulated ferroptosis resistance genes and to better characterise NRF2 target genes. RNA sequencing was also performed to identify gene expression after treatment with pro-ferroptotic iron-oxide nanoparticles. Results: TSC2-deficient cells exhibited resistance to RSL3 and erastin-induced ferroptosis, which correlated with increased ferroptosis defence gene expression, including NRF2 and downstream targets. NRF2 inhibition re-sensitised TSC2-deficient cells to ferroptosis, confirming its protective role. However, FSP1 inhibition did not re-sensitise TSC2-deficient angiomyolipoma kidney tumor cells to RSL3. In contrast, FSP1 knockdown significantly enhanced ferroptosis sensitivity in ovarian (PEO1, PEO4, OVCAR3) and breast (MDA-MB-436) cancer cell lines. Notably, in MDA-MB-436 cells, FSP1 knockdown was more effective than NRF2 inhibition in reversing ferroptosis resistance. Conclusions: Our findings highlight NRF2 and FSP1 as key regulators of ferroptosis resistance in TSC2-deficient and cancer cells. However, the differential efficacy of targeting these pathways suggests that patient stratification may be necessary for optimal therapeutic strategies. Targeting NRF2 and FSP1 could enhance ferroptosis susceptibility, offering a potential therapeutic approach for ferroptosis resistance cancers.

Project description:Ferroptotic cell death is dependent on unrestricted lipid peroxidation rather than activation of apoptotic effector caspases. A large number of ferroptosis activators have been reported recently. We used gene sequencing to analyze the effects of four ferroptosis activators (RSL3, N6F11, Fin56 and Erastin) on global gene expression in human PDAC1 cell line.

Project description:Breast tumors develop in a complex microenvironment whose main component is adipose tissue and gain aggressiveness through increased fatty acid uptake. Here, we demonstrated that palmitic acid (PA) induced ferroptosis in triple negative breast cancers (TNBC). We found that PA increases the protein expression levels of the long-chain fatty acid transporter CD36 leading to increased lipid uptake. Mechanistically, overexpression of CD36 increases lipid peroxidation, mitochondrial ROS production, the labile iron pool and especially Fe2+ content. Additionally, we found increased expression of ferroptotic target genes (HMOX1, ACSL1, SAT1) and decreased of anti-ferroptotic genes (GPX4 and FSP1) in TNBC following PA exposure. Overexpression of CD36 did not induce ferroptosis in estrogen receptor positive breast cancer. Clinically, higher CD36 expression correlated with the luminal androgen receptor (LAR) subtype of TNBC, known to exhibit a higher sensitivity to ferroptosis. Altogether, these data provide evidence for an essential role of the CD36 protein in the ferroptotic process induced by the saturated fatty acid PA, opening potential new therapeutic approaches promoting ferroptosis in the most aggressive breast cancers.

Project description:Membrane protection against oxidative damage is tightly buffered by glutathione peroxidase 4 (GPX4), and endogenous radical-trapping antioxidants such as ubiquinone, vitamin E and K. Deficiencies in these protective systems have been linked to the accumulation of phospholipid peroxidation and ferroptosis induction. Recently, ferroptosis suppressor protein 1 (FSP1) was identified as a key player in this process, preventing phospholipid peroxidation and ferroptosis by regenerating radical-trapping antioxidants. Yet, regulators of FSP1 have remained largely unknown, and their identification is critical for understanding the mechanism regulating phospholipid peroxidation and ferroptosis. In this study, we conducted a CRISPR-Cas9 screen to uncover factors influencing FSP1 function, identifying vitamin B2 (riboflavin) as a yet-unaccounted modulator of ferroptosis sensitivity. We demonstrate that vitamin B2, unlike other vitamins that directly act as radical-trapping antioxidants, facilitates the recycling of lipid-soluble antioxidants by directly supporting FSP1 stability and activity, thereby mitigating phospholipid peroxidation. Thus, we uncovered a direct role of vitamin B2 in maintaining membrane integrity and supporting membrane tolerance to lipid peroxidation and ferroptosis resistance. Our findings provide a rational strategy to modulate the FSP1-antioxidant recycling pathway, with potential implications for treating cancer and other diseases where ferroptosis plays a pivotal role.

Project description:Cancer persister cells which survive oncogene targeted therapies are sensitized to ferroptosis but mechanistic understanding of this vulnerability remains limited. Here, we found that while levels of iron, glutathione and various ferroptosis suppressing enzymes vary among persister cell types, ferroptosis suppressor protein 1 (FSP1) is downregulated in multiple persister cell types and persister cells which survive glutathione peroxidase 4 (GPX4) inhibition rely upon residual FSP1 to survive. Furthermore, persister cells which survive GPX4 inhibition downregulate oxidative phosphorylation, a key source of mitochondrial reactive oxygen species which are required for persister cell ferroptosis. We also found that persister cell treatment with histone deacetylase inhibitors induce reactive oxygen species and sensitize multiple persister cell types to GPX4 inhibition. Together, these findings reveal that FSP1 and histone deacetylases suppress persister cell ferroptosis.

Project description:We discovered, through untargeted metabolomics, that creatine promotes ferroptosis in colorectal cancer. Our study identifies ERK2 as a creatine sensor that mediates active FSP1 and ferroptosis resistance, and highlights the potential of targeting tumor SLC6A8 for cancer treatment.

Project description:Diquat (DQ) poisoning is a severe medical condition with life-threatening implications and multi-organ dysfunction, yet its underlying mechanism remains incompletely understood. This study unveils a critical process in DQ-induced toxicity. DQ disrupts the mitochondrial genome stability in endothelial cells, leading to the accumulation of Z-form DNA. This triggers an interaction between Z-DNA binding protein 1 (ZBP1) and receptor interacting protein kinase 3 (RIPK3), setting off RIPK3-dependent necroptotic and ferroptotic signaling pathways. Depletion of ZBP1 or RIPK3 in endothelial cells effectively inhibits both necroptosis and ferroptosis, reducing organ damage and mortality. Importantly, we discover that RIPK3 plays a dual role. It phosphorylates MLKL to induce necroptosis and phosphorylates FSP1, inhibiting its enzymatic activity and promoting ferroptosis. The phosphorylation of T163 in FSP1 is crucial for suppressing its activity. Combining the deletion of MLKL with vitamin K treatment proves highly effective in mitigating multi-organ damage and lethality caused by DQ.

Project description:Assays in bile duct cancer patients showed 984 CNVs in 306 CNV regions (CNVR) distributed throughout all 22 chromosomes. Bile duct cancer patients had a mean of 21.8 gains and 19.2 losses of genes, with an average of 35.9 CNVRs per patient. Frequent sites of gains were at chromosomes 22q11.22, 2p11.2-p.11.1, 14q32.33 and 17q12, whereas frequent sites of losses were at 19q12-q13.43. Investigation of CNV in 24 bile duct cancer tissue samples

Project description:Ferroptosis is a form of regulated cell death driven by the iron-dependent accumulation of oxidized polyunsaturated-fatty-acid-containing phospholipids (PUFA-PLs). Three key molecular features of ferroptosis are peroxidation of PUFA-PLs, accumulation of redox-active ferrous iron, and defective lipid peroxide repair (Dixon and Stockwell, 2019). However, there is currently no reliable way to selectively stain ferroptotic cells in tissue sections to characterize the extent of ferroptosis in animal models of disease and in patient tissue samples. We sought to address this gap by immunizing mice with membranes from lymphoma cells treated with the ferroptosis inducer piperazine erastin (PE), and screening ~4,750 of the resulting monoclonal antibodies generated for their ability to selectively detect cells undergoing ferroptosis. We found that one antibody, termed 3F3 Ferroptotic Membrane Antibody (3F3-FMA), was effective as a selective ferroptosis-staining reagent using immunofluorescence (IF). The antigen of 3F3-FMA was identified by immunoprecipitation and mass spectrometry as the human transferrin receptor 1 protein (TfR1), which imports iron from the extracellular environment into cells. We validated this finding with several additional anti-TfR1 antibodies, and compared them to other potential ferroptosis-detecting reagents via immunofluorescence staining, using fluorescence microscopy and flow cytometry. We found that anti-TfR1 and anti-malondialdehyde (MDA) adduct antibodies were effective at reliably staining ferroptotic tumor cells in numerous cell culture and tissue contexts. In summary, these findings suggest that anti-TfR1 antibodies can be used to selectively label cells undergoing ferroptosis.