Project description:Melanin Nanoparticles Alleviates Thalamic Stroke Damage by Modulating Glial Activation and Neuroinflammation

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:While the importance of the iron-load of lipocalin-2 (Lcn-2) in promoting tumor progression is widely appreciated, underlying molecular mechanisms largely remain elusive. Considering its role as an iron-transporter, we aimed at clarifying iron-loaded, holo-Lcn-2 (hLcn-2)-dependent signaling pathways in affecting renal cancer cell viability. Applying RNA sequencing analysis in renal CAKI1 tumor cells to explore highly upregulated molecular signatures in response to hLcn-2, we identified a cluster of genes (SLC7A11, GCLM, GLS), which are implicated in regulating ferroptosis. Indeed, hLcn-2-stimulated cells are protected from erastin-induced ferroptosis. We also noticed a rapid increase in reactive oxygen species (ROS) with subsequent activation of the antioxidant Nrf2 pathway. However, knocking down Nrf2 by siRNA was not sufficient to induce erastin-dependent ferroptotic cell death in hLcn-2-stimulated tumor cells. In contrast, preventing oxidative stress through N-acetyl-L-cysteine (NAC) supple-mentation was still able to induce erastin-dependent ferroptotic cell death in hLcn-2-stimulated tumor cells. Besides an oxidative stress response, we noticed activation of the integrated stress response (ISR), shown by enhanced phosphorylation of eIF-2α and induction of ATF4 after hLcn-2 addition. ATF4 knockdown as well as inhibition of the ISR sensitized hLcn-2-treated renal tumor cells to ferroptosis, thus linking the ISR to pro-tumor characteristics of hLcn-2. Our study provides mechanistic details to better understand tumor pro-survival pathways initi-ated by iron-loaded Lcn-2.

Project description:This study investigates the molecular mechanisms by which L-proline contributes to heart failure with preserved ejection fraction (HFpEF) through ferroptosis. L-proline was found to exacerbate ferroptotic stress in cardiac tissue, partly by modulating the expression of key antioxidant and lipid metabolism genes. Notably, L-proline suppressed PPARγ signaling, a critical regulator of ferroptosis resistance and metabolic homeostasis. Downregulation of PPARγ led to activation of pro-ferroptotic mediators, including ACSL4 and TFR1, suggesting a mechanistic link between amino acid metabolism and cardiac vulnerability in HFpEF.

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.

Project description:Ferroptosis, a non-apoptotic form of programmed cell death, is triggered by oxidative stress in cancer, heat stress in plants and hemorrhagic stroke. A homeostatic transcriptional response to ferroptotic stimuli is unknown. We show that neurons respond to ferroptotic stress by induction of a transcriptional adaptive response. Pharmacological selenium (Se) augments mitochondrial and nuclear GPX4 and other genes in this transcriptional program, the selenome, via coordinated activation of the transcription factors TFAP2c and Sp1, to protect neurons. This RNA seq data uses primary cortical neurons in cultures treated with either homocysteic acid (HCA), which induces ferroptosis and/or Se, which augments the adaptation to ferroptosis. Both protective (1mM Se) and non-protective (0.1mM Se) of selenium are used. Cells are collected after 6 hours when the transcriptional response is observed.

Project description:Ferroptosis is a form of regulated cell death characterized by iron-dependent lipid peroxidation. While ferroptosis has been identified as a mechanism for suppressing cancer, its overall physiological significance remains poorly understood. Recent studies have revealed that labile iron and lipid peroxides are released from ferroptotic cells, leading to the propagation of ferroptosis through lipid peroxidation. However, other specific effects of secreted factors derived from ferroptotic cells remain unclear. We constructed a model cell system capable of inducing ferroptosis by re-expressing the transcription factor BACH1, a potent inducer of ferroptosis, in immortalized mouse embryonic fibroblasts (iMEFs). We investigated the impact of the secreted factors from ferroptotic cells with the iMEFs. As a result, we observed that the administration of supernatant media from ferroptotic iMEFs activated proliferation of hepatoma cells and suppressed cellular senescence-like features. This suggested that ferroptotic MEFs secrete anti-senescent substances. Transcriptome analysis of ferroptotic MEFs revealed an increase in the secretion of longevity factor FGF21 in a BACH1-dependent manner. Furthermore, the anti-senescent effects of the supernatant media from these ferroptotic cells were canceled by the knockout of Fgf21. Totally, it is suggested that BACH1 promotes ferroptosis in fibroblasts and contributes to the suppression of cellular senescence in neighboring cells by inducing FGF21 secretion from fibroblasts. It was also discovered that BACH1 not only activates indirectly the transcription of FGF21 by enhancing ferroptotic stress but also increases FGF21 protein level by suppressing the selective autophagic degradation of FGF21 through the transcriptional repression for Sqstm1 and Lamp2a. This represents a dual mechanism of FGF21 upregulation mediated by BACH1, suggesting that BACH1 is a potent inducer of FGF21 expression. It was also found that the BACH1-ferroptosis-FGF21 axis can suppress obesity of mice under high fat diet or short lifespan of progeria mice, closely associated phenotypes with aging. The inhibition of these aging-related phenotypes is considered to be a novel physiological significance of ferroptosis, and BACH1 is considered to function as a longevity gene by promoting ferroptotsis and subsequent FGF21 expression.

Project description:Cancers coopt stress-response pathways to drive oncogenesis, dodge immune surveillance, and resist cytotoxic therapies. Several of these provide protection from ferroptosis, iron-mediated oxidative cell death. Here, we found dramatic sensitization to ferroptosis upon disruption of cap-dependent translation in diffuse large B-cell lymphoma (DLBCL). Specifically, rocaglate inhibitors of the eIF4A1 RNA helicase synergized with pharmacologic ferroptosis inducers, driven by a collapse of glutathione production that protects polyunsaturated fatty acids from ferroptotic oxidation. These effects occur despite initial up-regulation of specific protective factors. We find lost translation of NRF2, oncogenic master regulator of antioxidant gene-expression, is a key consequence of eIF4A1 inhibition. In vivo, combination of the clinical rocaglate zotatifin with a pharmacologically optimized ferroptosis inducer eradicated DLBCL patient derived xenografts. Moreover, we found zotatifin pre-exposure sensitized DLBCL to CD19-directed chimeric antigen receptor (CAR-19) T cells. Translational disruption therefore provides new opportunities to leverage therapeutic impacts of ferroptosis inducers including cytotoxic immunotherapies.

Project description:Omega-3 polyunsaturated fatty acids (n-3 PUFAs) have long been associated with health benefits, including anti-inflammatory effects, but only few studies investigated the effects on kidney health. Preclinical data from animal models suggest that n-3 PUFAs may reduce glomerulosclerosis, albuminuria and inflammation, but the molecular mechanisms remain elusive. In this study, we investigated the potential protective effects of docosahexaenoic acid (DHA) on murine mesangial cells. However, stimulation with DHA alone led to a substantial reduction in viability and ultimately to cell death. Proteomic profiling identified a significant upregulation of ferroptosis, including the increased abundance of the key pro-ferroptotic protein HMOX1 and simultaneous downregulation of the pro-ferroptotic proteincs TFRC and ACSL4. These finding indicate an imbalance of cellular pro- and anti-ferroptotic self-protection mechanisms in DHA-treated cells. On the contrary, treatment with Ferrostatin-1, a known ferroptosis inhibitor, preserved cellular metabolic activity and prevented cell death, strongly supporting a role of ferroptosis in DHA-induced cytotoxicity. Furthermore, co-treatment with DHA and an antioxidant cocktail also significantly attenuated DHA-induced cell death and induced upregulation of several key anti-ferroptotic proteins, including TXNRD1 and GPX4, while further downregulating pro-ferroptotic proteins such as TFRC and ASCL4. Our findings provide novel insights into the ferroptotic response induced by DHA in mesangial cells and highlight the potential of antioxidant co-treatment to counteract this effect. This underscores the importance of a balance between pro- and anti-ferroptotic mechanisms in therapeutic strategies using n-3 PUFAs to promote kidney health.

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.