Project description:Understanding the mechanisms underlying evasive resistance in cancer is an unmet medical need to improve the efficacy of current therapies. In this study, a combination of shRNA-mediated synthetic lethality screening and transcriptomic analysis revealed the transcription factors YAP/TAZ as key drivers of Sorafenib resistance in hepatocellular carcinoma (HCC) by repressing Sorafenib-induced ferroptosis. Mechanistically, in a TEAD-dependent manner YAP/TAZ induce the expression of SLC7A11, a key transporter maintaining intracellular glutathione homeostasis, thus enabling HCC cells to overcome Sorafenib-induced ferroptosis. At the same time, YAP/TAZ sustain the protein stability, nuclear localization and transcriptional activity of ATF4 which in turn cooperates to induce SLC7A11 expression. Our study uncovered a critical role of YAP/TAZ in the repression of ferroptosis and thus in the establishment of Sorafenib resistance in HCC, highlighting YAP/TAZ-based rewiring strategies as potential approaches to overcome HCC therapy resistance.

Project description:To investigate the molecular mechanism of ferroptosis resistance in HCC, we applied sorafenib, one of the class I ferroptosis inducers (FINs), to generate HepG2 sorafenib resistant (SR) cells.

Project description:Earlier studies linked sorafenib effectiveness to induction of ferroptosis. Herein we demonstrate sorafenib and mTKIs downregulate DDX5 in vitro and in vivo. To understand the effect of DDX5 downregulation, we compared TCGA-derived HCCs expressing low vs. high DDX5 focusing on ferroptosis-related genes. Glutathione Peroxidase 4 (GPX4), a key ferroptosis regulator, was significantly overexpressed in DDX5LOW HCCs. Importantly, DDX5-knockdown (DDX5KD) HCC cell lines lacked lipid peroxidation by GPX4 inhibition, indicating DDX5 downregulation suppresses ferroptosis. RNAseq analyses comparing wild type vs. DDX5KD cells in the presence or absence of sorafenib, identified a unique set of genes repressed by DDX5 and upregulated by sorafenib. This set significantly overlaps genes from Wnt/β-catenin and non-canonical NF-κB pathways, including NF-κB inducing Kinase required for non-canonical NF-κB activation. Pharmacologic inhibition of these pathways in combination with sorafenib reduced DDX5KD cell viability. Mechanistically, sorafenib-mediated NF-κB activation induced NRF2 transcription, while DDX5KD extended NRF2 half/life by stabilizing p62/SQSTM1, leading to enhanced expression of GPX4 and ferroptosis escape. Conclusion: Sorafenib/mTKI-mediated DDX5 downregulation results in adaptive mTKI resistance by enhancing NRF2 expression, leading to ferroptosis escape. We propose inhibition of the pathways leading to NRF2 expression will enhance the therapeutic effectiveness of sorafenib/mTKIs.

Project description:Sorafenib is the first-line treatment for advanced stage hepatocellular carcinoma (HCC), but rapid disease re-progression occurs in most treated cases, with molecular mechanism remaining elusive. The resistance to sorafenib has been correlated with inflammation, and here we investigated how the pro-inflammatory TIFA signaling modulates the inflammatory tumor microenvironment to negate sorafenib cytotoxicity and prime for HCC dissemination. We found that the TIFA-NF-κB axis in HCC cells compromised sorafenib cytotoxicity in alliance with pro-tumor M2 macrophages, suggesting an intensive crosstalk between HCCs and M2 macrophages. To identify the key mediators of such crosstalk between HCC cells and macrophages underlying sorafenib resistance, primary macrophages were cocultured with HCC cells and then subjected to targeted RNA-panels for transcriptome analysis of innate immune and inflammatory factors.

Project description:Ferroptosis is a new form of regulated, non-apoptotic cell death characterized by excessive lipid peroxidation upon loss of activity of the lipid repair enzyme glutathione peroxidase 4 (GPX4). Sorafenib, an FDA-approved multi-kinase inhibitor drug for treatment of hepatocellular carcinoma (HCC), has been shown to induce ferroptosis. Protein phosphorylation changes upon Sorafenib treatment have been previously reported in patient studies and in cell culture however the early phosphorylation changes during induction of ferroptosis are not completely understood. This work highlights these changes through a time course from 7 to 60 min of Sorafenib treatment in SKHep1 cells to provide insight on the induction of ferroptosis. 6,186 unique phosphosites were quantified from 2,381 phosphoproteins in this study and phosphorylation changes occurred in as early as 30 minutes of Sorafenib treatment. By 60 minutes, significant changes in key regulatory pathways were identified, including sites from ferroptosis-related proteins, indicating the involvement of phospho-regulated signaling during ferroptosis induction.

Project description:N6-methyladenosine (m6A) is a type of nucleotide modification abundant in mRNA, which regulates mRNA stability, splicing and translation. However, its physiological role in intratumoral microenvironment and drug resistancehave not been fully understood. We demonstrated that METTL3,a primary m6A methyltransferase, was significantly down-regulated in human sorafenib-resistant hepatocellular carcinoma (HCC). Depletion of METTL3 under hypoxia promoted sorafenib-resistance and angiogenesis and exacerbated progression by activating autophagy-associated pathway. Mechanistically, we identified FOXO3 as a key downstream target of the METTL3-mediated m6A modification. The m6A modification of FOXO3 at the 3'-untranslated region increased FOXO3 mRNA stability. Analysis of clinical samples showed that METTL3levels aretightly correlated with FOXO3levels in patients with HCC, and suppression of FOXO3 predicted poor clinical outcomes. Importantly, METTL3-depletion significantly enhanced sorafenib-resistance of HCC via a METTL3-FOXO3 axis, whereasoverexpression of FOXO3 restored the m6A-dependent sorafenib-sensitivity. Collectively, our work revealedthe critical function of the METTL3-mediated m6A modification in HCC in hypoxic tumor microenvironment, and provided insights into the molecular mechanism of the m6A modification in the resistance of HCC to sorafenib therapy.

Project description:N6-methyladenosine (m6A) is a type of nucleotide modification abundant in mRNA, which regulates mRNA stability, splicing and translation. However, its physiological role in intratumoral microenvironment and drug resistancehave not been fully understood. We demonstrated that METTL3,a primary m6A methyltransferase, was significantly down-regulated in human sorafenib-resistant hepatocellular carcinoma (HCC). Depletion of METTL3 under hypoxia promoted sorafenib-resistance and angiogenesis and exacerbated progression by activating autophagy-associated pathway. Mechanistically, we identified FOXO3 as a key downstream target of the METTL3-mediated m6A modification. The m6A modification of FOXO3 at the 3'-untranslated region increased FOXO3 mRNA stability. Analysis of clinical samples showed that METTL3levels aretightly correlated with FOXO3levels in patients with HCC, and suppression of FOXO3 predicted poor clinical outcomes. Importantly, METTL3-depletion significantly enhanced sorafenib-resistance of HCC via a METTL3-FOXO3 axis, whereasoverexpression of FOXO3 restored the m6A-dependent sorafenib-sensitivity. Collectively, our work revealedthe critical function of the METTL3-mediated m6A modification in HCC in hypoxic tumor microenvironment, and provided insights into the molecular mechanism of the m6A modification in the resistance of HCC to sorafenib therapy.

Project description:Hepatocellular carcinoma (HCC) is one of the most frequent malignancies with extremely poor prognosis. Clinical efficacies of existing targeted therapy strategies were not satisfied due to targeted therapy resistance. In this study, we performed a series of CRISPR/Cas9 screens to identify synthetic lethality genes to improve the clinical response of HCC. CRISPR loss-of-function genetic screens were performed to identify synthetic lethality genes of targeted therapies (Abemaciclib, Palbociclib, Sorafenib, Lenvatinib, Regorafenib and Erastin) in HCC cell lines. RNA-seq analysis were performed to clarify potential mechanism. We identified that inhibition of phosphoseryl-tRNA kinase (PSTK) sensitized HCC cells to targeted therapies. PSTK contributes to resistance of targeted therapy induced ferroptosis.

Project description:Sorafenib resistance up-regulated circRNA_104797 could be transmitted by exosomes and responsible for the spread of Sorafenib resistance among HCC cells. CircRNA_104797 was critical for Sorafenib resistance maintenance and silencing circRNA_104797 could substantially increase the efficacy of Sorafenib by inducing apoptosis. Mechanism dissection unveiled that circRNA_104797 could specifically sponge miR-103a-2-5p and miR-660-3p and act as a competing endogenous RNA (ceRNA), thus competitively activated wnt/β-catenin pathway and induced Sorafenib resistance. Meanwhile, LC-MS/MS also revealed that circRNA_104797 could specifically bind to translation related proteins, which might regulate downstream glycan biosynthesis and lipid metabolism, and finally induce Sorafenib resistance. In vivo experiments portrayed a promising clinical application by locally injection of in vivo-grade siRNA for circRNA_104797 by TACE or other manners, which could intensively enhance Sorafenib efficacy in HCC patients. The clinical application of in vivo-grade siRNA for circRNA_104797 in Sorafenib treated HCC patients might shed bright future for the management of advanced HCC.

Project description:OBJECTIVE: Sorafenib is effective in hepatocellular carcinoma (HCC), but patients ultimately present disease progression. Molecular mechanisms underlying acquired resistance are still unknown. Herein, we characterize the role of tumor-initiating cells (T-ICs) and signaling pathways involved in sorafenib resistance. DESIGN: HCC xenograft mice treated with sorafenib (n=22) were explored for responsiveness (n=5) and acquired resistance (n=17). Mechanism of acquired resistance were assessed by: 1) Role of T-ICs by in vitro sphere formation and in vivo tumorigenesis assays using NOD/SCID mice, 2) Activation of alternative signaling pathways and 3) Efficacy of anti-FGF and anti-IGF drugs in experimental models. Gene expression (microarray, qRT-PCR) and protein analyses (immunohistochemistry, western blot) were conducted. A novel gene signature of sorafenib resistance was generated and tested in 2 independent cohorts. RESULTS: Sorafenib-acquired resistance tumors showed significant enrichment of T-ICs (164 cells needed to create a tumor) vs. sorafenib-sensitive tumors (13400 cells) and non-treated tumors (1292 cells), p<0.001. Tumors with sorafenib-acquired resistance were enriched with IGF and FGF signaling cascades (FDR<0.05). In vitro, cells derived from sorafenib-acquired resistant tumors and two sorafenib-resistant HCC cell lines were responsive to IGF or FGF inhibition. In vivo, FGF blockade delayed tumor growth and improved survival in sorafenib-resistant tumors. A sorafenib-resistance 175-gene signature was characterized by enrichment of progenitor-cell features, aggressive tumoral traits and predicted poor survival in 2 cohorts (n=442 HCC patients). CONCLUSION: Acquired resistance to sorafenib is driven by tumor initiating cells with enrichment of progenitor markers and activation of IGF and FGF signaling. Inhibition of these pathways would benefit a subset of patients after sorafenib progression. Transcriptomic profile of subcutaneous Huh7 cells-derived tumors treated with sorafenib that developed acquired resistance to the drug (n=4), remain responsive to sorafenib (n=3) or were treated with brivanib after development of resistance (n=3). Gene profiling of hepatospheres generated from tumors with acquired resistance to sorafenib (n=3) and non-treated tumors (n=3) was also analyzed.