Project description:ß-catenin is a main oncogene in a large number of cancers (colorectal, liver, melanoma, uterus). Local immunosuppression induced by certain cancers remains a major problem of resistance to immunotherapies and its molecular mechanism remains poorly understood. Recently, ß-catenin mutated tumors (hepatocellular carcinoma (HCC) and melanoma) have been described as promoting immune evasion and resistance to anti-PD1 immunotherapy. Based on preliminary data obtained in HCC, we hypothesize that a defect in intercellular communication could be the cause of this immune evasion. The main objective of this project is to identify proteomic signatures of factors that can induce this immune escape in ß-catenin mutated HCC such as exosomes.

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.

Project description:Sorafenib is a first-line chemotherapy drug for treating advanced hepatocellular carcinoma (HCC). However, its therapeutic effect has been seriously affected by the emergence of sorafenib resistance in HCC patients. The underlying mechanism of sorafenib resistance is unclear. Here, we report a circular RNA, cDCBLD2, which plays an important role in sorafenib resistance in HCC. We found that cDCBLD2 was upregulated in sorafenib-resistant (SR) HCC cells, and knocking down cDCBLD2 expression could significantly increase sorafenib-related cytotoxicity. Further evidence showed that cDCBLD2 can bind to microRNA (miR)-345-5p through a competing endogenous RNA mechanism, increase type IIA topoisomerase (TOP2A) mRNA stability through a miRNA sponge mechanism, and reduce the effects of sorafenib treatment on HCC by inhibiting apoptosis. Our findings also suggest that miR-345-5p can negatively regulate TOP2A levels by binding to the coding sequence region of its mRNA. Additionally, targeting cDCBLD2 by injecting a specific small interfering RNA (siRNA) could significantly overcome sorafenib resistance in a patient-derived xenograft (PDX) mouse model of HCC. Taken together, our study provides a proof-of-concept for a potential strategy to overcome sorafenib resistance in HCC patients by targeting cDCBLD2 or TOP2A.

Project description:Circular RNAs (circRNAs) are increasingly gaining importance and attention due to their diverse potential functions. Our study aims to explore the novel mechanisms by which exosome-contained circRNAs promote sorafenib resistance in hepatocellular carcinoma (HCC). Here we report that a circular RNA, circRNA-MANBA (a circular RNA upregulated in exosomes derived from sorafenib-resistant HCC cells), plays a significant role in sorafenib resistance in HCC. We identified that circRNA-MANBA is increased in sorafenib-resistant HCC cells, their exosomes, and tumor samples from sorafenib-treated HCC patients. Depletion of circRNA-MANBA substantially increases the cell-killing ability of sorafenib. Co-culture experiments revealed that exosomes from sorafenib-resistant HCC cells carrying large amounts of circRNA-MANBA could transmit drug resistant capacity to parental cells. Further studies revealed that circRNA-MANBA acted as ‘miRNAs sponge’ to absorb miR-1290, which prevented miR-1290 interaction with CD109 and thus upregulated STAT3 phosphorylation subsequently. Using different HCC mouse models, we demonstrated that silencing circRNA-MANBA by injection of siRNA could substantially overcome sorafenib resistance. Our study provides a proof-of-concept demonstration for a potential strategy to overcome sorafenib resistance in HCC patients by targeting circRNA-MANBA.

Project description:URI keeps low levels of p53 in a TRIM28-MDM2 dependent manner, maintains SCD1 activity and accumulation of MUFAs, and subsequently promotes resistance to TKIs in cancer cell. URI-p53-SCD1 axis mediates resistance of TKIs and may explain why p53-wild type HCC still showed intrinsic resistance to TKIs. Moreover, the combination therapy identified here may represent a promising strategy for the approximately 41% of patients with advanced HCC who have wild-type p53 and high levels of URI/SCD1.

Project description:Hepatocellular carcinoma (HCC) remains one of the most lethal cancers, characterized by poor prognosis and low life expectancy. Unfortunately, there are very few molecular therapeutic options available for advanced HCC. Sorafenib is a current standard first-line treatment for advanced HCC, but drug resistance significantly limits its therapeutic efficacy. In this study, we identified ubiquitin-specific protease 22 (USP22) as the key regulator of HCC development and Sorafenib resistance. Analysis of TCGA databases revealed that USP22 is highly expressed in HCC tissues and is closely associated with poor patient prognosis. Our data further indicated that USP22 promotes the proliferation of HCC cells via deubiquitinating and stabilizing cyclin-dependent kinase 11B (CDK11B). Additionally, USP22 acts as a novel inducer of Sorafenib resistance and suppresses Sorafenib-triggered ferroptosis in HCC cells. It reduces the transcription of the transferrin receptor (TFRC) by decreasing H2BK120ub occupancy at TFRC transcription start site (TSS) downstream region, thereby inhibiting ferroptosis upon Sorafenib treatment. Finally, animal experiments confirmed the role of USP22 in promoting HCC cell growth and Sorafenib resistance in vivo. Taken together, our findings suggest that USP22 represents a promising prognostic biomarker and therapeutic target for HCC patients, particularly those with Sorafenib resistance.

Project description:Hepatocellular carcinoma (HCC) remains one of the most lethal cancers, characterized by poor prognosis and low life expectancy. Unfortunately, there are very few molecular therapeutic options available for advanced HCC. Sorafenib is a current standard first-line treatment for advanced HCC, but drug resistance significantly limits its therapeutic efficacy. In this study, we identified ubiquitin-specific protease 22 (USP22) as the key regulator of HCC development and Sorafenib resistance. Analysis of TCGA databases revealed that USP22 is highly expressed in HCC tissues and is closely associated with poor patient prognosis. Our data further indicated that USP22 promotes the proliferation of HCC cells via deubiquitinating and stabilizing cyclin-dependent kinase 11B (CDK11B). Additionally, USP22 acts as a novel inducer of Sorafenib resistance and suppresses Sorafenib-triggered ferroptosis in HCC cells. It reduces the transcription of the transferrin receptor (TFRC) by decreasing H2BK120ub occupancy at TFRC transcription start site (TSS) downstream region, thereby inhibiting ferroptosis upon Sorafenib treatment. Finally, animal experiments confirmed the role of USP22 in promoting HCC cell growth and Sorafenib resistance in vivo. Taken together, our findings suggest that USP22 represents a promising prognostic biomarker and therapeutic target for HCC patients, particularly those with Sorafenib resistance.

Project description:Cancer cells voraciously consume nutrients to support their growth, exposing a metabolic vulnerability that can be therapeutically exploited. Here we show in hepatocellular carcinoma (HCC) cells, xenografts, and in patient-derived HCC organoids that fasting can synergistically sensitise resistant HCC to sorafenib. Mechanistically, sorafenib acts non-canonically as inhibitor of mitochondrial respiration, causing resistant cells to depend on glycolysis for survival. Fasting, through reduction in glucose and impeded AKT/mTOR-signalling, prevents this Warburg shift. p53 is necessary and sufficient for the sorafenib-sensitizing effect of nutrient restriction and crucial for improvement of sorafenib efficacy through intermittent fasting (IF) in an orthotopic HCC mouse model. Together, our data indicate IF and sorafenib as clinically actionable, rational combination therapy for HCC with intact p53 signalling. As HCC therapy is currently severely limited by resistance, these results should instigate clinical studies with the goal of improving therapy response in advanced-stage, and possibly even early-stage, HCC.

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:Sorafenib is a multi-kinase blocker and one of the few suggested drug treatments for aggressive hepatocellular carcinoma (HCC) patients. However, drug resistance to sorafenib may often occur over time and cause further tumor aggression. Recently, cancer stem cells were found in HCC and were speculated to be involved in tumor progression. SOX9 is highly expressed in HCC cancer stem cells and promotes cell proliferation and self-renewal. Meanwhile, HCC patients with higher SOX9 expression show poorer prognosis [1]. Whether SOX9 is involved in sorafenib resistance in HCC is still unclear. Here, we found that sorafenib treatment increased SOX9 expression in HCC cell lines. Overexpression of exogenous SOX9 in HCC increased sorafenib resistance both in vitro and in vivo, whereas down-regulation led to inhibition of sorafenib resistance. Knock-down of SOX9 by RNA interference caused down-regulation of downstream genes, including ATP binding cassette subfamily G member 2 (ABCG2). The drug resistance to sorafenib caused by SOX9 overexpression could be ameliorated by overexpression of SOX9 in combination withby ABCG2 inhibition in HCC cell lines. In the cohort of patients resistant to sorafenib, we found that patients with lower SOX9 expression had more prolonged overall survival (OS) and progression-free survival (PFS). Cox analysis shows that SOX9 expression exerts as an independent risk factor for HCC, and logistic regression analysis reveals that SOX9 expression, tumor capsule deficiency, tumor diameters, and microvascular invasion are risk factors for poor prognosis of HCC patients. These findings demonstrate that SOX9 enhances sorafenib resistance and may regulate this process by modulating ABCG2 expression.