Project description:Compared to the well-established roles of apoptosis in tumor suppression, the roles and regulatory mechanisms of ferroptosis, a non-apoptotic form of cell death, in tumor biology remain much less understood. BRCA1-associated protein 1 (BAP1) encodes a nuclear de-ubiquitinating (DUB) enzyme to reduce histone 2A ubiquitination (H2Aub) on chromatin, and is a tumor suppressor in several human cancers. Here, integrated transcriptomic, epigenomic, and cancer genomic analyses link BAP1 to metabolism-related biological processes, including oxidative stress response, and identify cystine transporter SLC7A11 as a BAP1-repressed target gene with high relevance to BAP1-mediated tumor suppression in human cancers. Functional studies reveal that BAP1, in a DUB-dependent manner, decreases H2Aub occupancy on the SLC7A11 promoter and represses SLC7A11 expression, and that BAP1 inhibits cystine uptake and promotes ferroptosis through repressing SLC7A11 expression. Finally, we show that BAP1 inhibits tumor development partly through SLC7A11, and that cancer-associated BAP1 mutants lose their abilities to repress SLC7A11 and to promote ferroptosis. Together, the results of our study show that BAP1 executes its tumor suppression function at least partly through its regulation of SLC7A11 and ferroptosis, and uncover a previously unappreciated mechanism coupling ferroptosis to tumor suppression.

Project description:Acute kidney injury (AKI) is a common and life-threatening condition associated with cell death, where ferroptosis plays a critical role. Chemerin, primarily produced in white adipose tissue, has multiple biological functions in renal pathophysiology. However, to date, whether and how chemerin regulates the progression of AKI remain unclear. Here, we found that chemerin expression was reduced in both AKI model mice and cells. Similarly, serum chemerin levels were also decreased in AKI patients. The administration of recombinant chemerin improves renal function in ischemia-reperfusion (I/R) model mice. Chemerin significantly attenuates ferroptosis in kidneys. In TCMK-1 cells, chemerin knockdown further aggravates ferroptosis. Mechanistically, chemerin activates AMP-activated protein kinase (AMPK), which induces the phosphorylation of nuclear factor erythroid 2-related factor 2 (NRF2) in renal tubular cells. Subsequently, NRF2 translocates into the nucleus, where it stimulates the expression of cystine/glutamate antiporter solute carrier (SLC7A11). As a result, cystine uptake and glutathione (GSH) biosynthesis in renal tubular cells were increased, which confers cells with higher capacity against ferroptosis. Overall, our findings indicate that chemerin plays a protective role in AKI by repressing ferroptosis in renal tubular cells, which is likely due to the activation in the AMPK/NRF2/SLC7A11 axis.

Project description:We established a comprehensive temporal dynamic response profile of a large set of BAC-GFP HepG2 cell lines representing the following components of stress signaling: i) unfolded protein response (UPR) [ATF4, XBP1, BIP and CHOP]; ii) oxidative stress [NRF2, SRXN1, HMOX1]; iii) DNA damage [P53, P21, BTG2, MDM2]; and iv) NF-κB pathway [A20, ICAM1]. Using logic-based ordinary differential equation (Logic-ODE), we modelled the dynamic profiles of the different stress responses and extracted specific descriptors potentially predicting the progressive outcomes. Please see the most updated version on GitHub: https://github.com/saezlab/LogicODE_GFP_SR

Project description:A systematic analysis of super-enhancers identified MLX as a potential oncogene in osteosarcoma. Knockdown of MLX impaired tumor aggressiveness in vitro and in vivo, suggesting oncogenic properties of MLX. Mechanistically, silencing of MLX downregulates SLC7A11, a key gene encoding glutamate/cystine antiporter, to attenuate the uptake of cystine and interrupt the redox balance, leading to ferroptotic cell death. Pharmacological inhibition of SLC7A11 triggered massive ferroptosis and caused impaired tumor growth, providing a promising approach for osteosarcoma treatment.

Project description:Triple-negative breast cancer (TNBC) has a highly aggressive nature and distinct molecular characteristics from other subtypes of breast cancer and lacks effective targeted therapy. The molecular and genetic basis of cysteine/cystine dependency in TNBC is complex. We found that cysteine addiction associates with the expression of a set of Claudin genes in TNBC. The Claudin-high TNBCs are independent on cystine, while the Claudin-low TNBCs undergo rapid ferroptosis upon cystine deprivation or inhibition of cystine transport by erastin. To overcome the resistance of Claudin-high TNBC and luminal breast cancer to the potential targeted cystine-addiction therapy, we explored the synthetic lethality of cysteine by an epigenetic compound library screen. Several potent HDAC6 inhibitors were identified and rendered the Claudin-high TNBCs and luminal cancer cells dependent on extracellular cystine and undergoing ferroptosis upon cystine deprivation. The transcriptomic profiling showed that the HDAC6 inhibitor tubacin in combination with erastin activates a synthetic-lethal transcriptional program. Together, we have identified the HDAC6 inhibitors as potent therapy-sensitizers to revive the targeted cysteine-addiction therapy for various subtypes of breast cancer, not limit in the Claudin-low TNBC.

Project description:The deubiquitinase activity of Bap1 modifies osteoclast function by metabolic reprogramming. Bap1 deficient osteoclast lineage cells upregulate the cystine transporter, Slc7a11, by enhanced H2Aub occupancy of its promoter. SLC7A11 controls cellular ROS levels and redirects the mitochondrial metabolites away from the TCA cycle, both of which are necessary for osteoclast function.

Project description:Enhanced autophagy is recognized as a component of the pathogenesis of smoking-induced airway disease. Based on the knowledge that enhanced autophagy is linked to oxidative stress and the DNA damage response, both of which are linked to smoking, we used microarray analysis of the small airway epithelium to identify smoking up-regulated genes known to re-spond to oxidative stress and the DNA damage response. This analysis identified OSGIN1 as significantly up-regulated by smoking in both the large and small airway epithelium (1.8-fold, p<0.01, 2.1-fold, p<10-4, respectively), an observation confirmed by an independent small airway microarray cohort, TaqMan PCR and RNAseq. Genome-wide correlation of RNAseq analysis of airway basal/progenitor cells isolated from healthy subjects (n=17) showed a direct correlation of OSGIN1 mRNA levels to multiple classic autophagy genes, including, LC3B, P62, WIPI1 and ATG13 (all rho>0.7, p<0.01). In vitro cigarette smoke extract exposure of nonsmoker primary airway basal/progenitor cells was accompanied by a dose-dependent up-regulation of OSGIN1 and autophagy induction. Lentivirus-mediated enhanced expression of OSGIN1 in human primary basal/progenitor cells induced puncta-like staining of LC3B and up-regulation of LC3B mRNA and protein and P62 mRNA expression level in a dose and time-dependent manner. OSGIN1-induction of autophagosome / amphistome / autolysosome formation was confirmed by co-localization of LC3B with P62 or CD63 (endosome marker) and LAMP1 (lysosome marker). Induction of autophagy by OSGIN1 is accompanied with heightened oxidative stress. Together, these observations support the concept that smoking-induced up-regulation of OSGIN1 is at least one link between smoking-induced stress and enhanced-autophagy in the human airway epithelium.

Project description:Enhanced autophagy is recognized as a component of the pathogenesis of smoking-induced airway disease. Based on the knowledge that enhanced autophagy is linked to oxidative stress and the DNA damage response, both of which are linked to smoking, we used microarray analysis of the small airway epithelium to identify smoking up-regulated genes known to re-spond to oxidative stress and the DNA damage response. This analysis identified OSGIN1 as significantly up-regulated by smoking in both the large and small airway epithelium (1.8-fold, p<0.01, 2.1-fold, p<10-4, respectively), an observation confirmed by an independent small airway microarray cohort, TaqMan PCR and RNAseq. Genome-wide correlation of RNAseq analysis of airway basal/progenitor cells isolated from healthy subjects (n=17) showed a direct correlation of OSGIN1 mRNA levels to multiple classic autophagy genes, including, LC3B, P62, WIPI1 and ATG13 (all rho>0.7, p<0.01). In vitro cigarette smoke extract exposure of nonsmoker primary airway basal/progenitor cells was accompanied by a dose-dependent up-regulation of OSGIN1 and autophagy induction. Lentivirus-mediated enhanced expression of OSGIN1 in human primary basal/progenitor cells induced puncta-like staining of LC3B and up-regulation of LC3B mRNA and protein and P62 mRNA expression level in a dose and time-dependent manner. OSGIN1-induction of autophagosome / amphistome / autolysosome formation was confirmed by co-localization of LC3B with P62 or CD63 (endosome marker) and LAMP1 (lysosome marker). Induction of autophagy by OSGIN1 is accompanied with heightened oxidative stress. Together, these observations support the concept that smoking-induced up-regulation of OSGIN1 is at least one link between smoking-induced stress and enhanced-autophagy in the human airway epithelium.

Project description:Integrated-systems model of oxidative stress connecting NRF2 and p53 signaling pathways. Additional crosstalk linking oxidative stress to p53 inhibition, p53 to NRF2 through p21, and NRF2 to MDM2 was incorporated in this model. The NRF2 pathway was encoded as first- and second-order rate equations for KEAP1 oxidation and NRF2 stabilization; NRF2-mediated transcription of antioxidant enzymes was modeled as a Hill function. The p53 pathway was reconstructed from a delay differential equation model of p53 signaling in response to DNA damage. To adapt the p53 DNA-damage model to respond to oxidative stress, we used a first-order oxidation reaction of ATM/CHEK2 by intracellular H2O2. The integrated base model of NRF2–p53 oxidative-stress signaling contains 42 reactions and 22 ordinary differential equations (ODEs).

Project description:Here, through genome-wide CRISPR-Cas9 screenings, we identified GAS41, a well-known histone reader as a major repressor for ferroptosis. GAS41 interacts with NRF2 and is critical for NRF2 to activate its targets such as SLC7A11 for modulating ferroptosis. By recognizing the H3K27-acetylation (H3K27-ac) marker, GAS41 is recruited to the SLC7A11 promoter independent of NRF2 binding. Notably, by bridging the interaction between NRF2 and the H3K27-ac marker, GAS41 acts as an anchor for NRF2 on chromatin in a promoter-specific manner for transcriptional activation. Moreover, the GAS41-mediated effect on ferroptosis contributes significantly to its oncogenic role in vivo. These data demonstrate that GAS41 is an important target for modulating tumor growth through ferroptosis. Our study reveals a previously unanticipated mechanism for GAS41-mediated regulation in transcription by anchoring NRF2 on chromatin and provides a model that the DNA binding activity on chromatin by transcriptional factors (NRF2) can be directly regulated by histone markers (H3K27-ac).