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Agnes Holczbauer,
Valentina M Factor,
Jesper B Andersen,
Jens U Marquardt,
David Kleiner, Chiara Raggi,
Mitsuteru Kitade,
Daekwan Seo,
Hirofumi Akita,
Marian Durkin,
Snorri S Thorgeirsson
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ABSTRACT: BACKGROUND & AIMS:: Human primary liver cancer (PLC) is classified into biologically distinct subgroups, based on cellular origin. Liver cancer stem cells (CSCs) have been recently described. We investigated the ability of distinct lineages of hepatic cells to become liver CSCs and the phenotypic and genetic heterogeneity of PLC. METHODS:: We transduced mouse primary hepatic progenitor cells (HPC), lineage-committed hepatoblasts, and differentiated adult hepatocytes with transgenes encoding oncogenic H-Ras and simian virus 40 large-T antigen. The CSC properties of transduced cells and their ability to form tumors were tested by standard in vitro and in vivo assays and transcriptome profiling. RESULTS:: Irrespective of origin, all transduced cells acquired markers of CSC/progenitor cells, side populations, and self-renewal capacity in vitro. They also formed a broad spectrum of liver tumors, ranging from cholangiocarcinoma to hepatocellular carcinoma, which resembled human liver tumors, based on genomic and histologic analyses. The tumor cells co-expressed hepatocyte (HNF4A), biliary progenitor cell (keratin 19, EpCAM, A6), and mesenchyme (vimentin) markers and showed disregulation of genes that control the epithelial–mesenchymal transition. Gene expression analyses could distinguish tumors of different cellular origin, indicating the contribution of lineage-stage dependent genetic changes to malignant transformation. Activation of c-Myc and its target genes was required to reprogram adult hepatocytes into CSC and for tumors to develop. Stable knockdown of c-Myc in transformed adult hepatocytes reduced their CSC properties in vitro and suppressed growth of tumors in immunodeficient mice. CONCLUSIONS:: Any cell type in the mouse hepatic lineage can undergo oncogenic reprogramming into a CSC, by activating different cell type-specific pathways. Identification of common and cell-of-origin specific phenotypic and genetic changes could provide new therapeutic targets for liver cancer.
Gastroenterology 03/2013; · 11.68 Impact Factor
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ABSTRACT: Hepatocyte growth factor (HGF)/c-Met supports a pleiotrophic signal transduction pathway that controls stem cell homeostasis. Here, we directly addressed the role of c-Met in stem-cell-mediated liver regeneration by utilizing mice harboring c-met floxed alleles and Alb-Cre or Mx1-Cre transgenes. To activate oval cells, the hepatic stem cell (HSC) progeny, we used a model of liver injury induced by diet containing the porphyrinogenic agent, 3,5-diethocarbonyl-1,4-dihydrocollidine (DDC). Deletion of c-met in oval cells was confirmed in both models by polymerase chain reaction analysis of fluorescence-activated cell-sorted epithelial cell adhesion molecule (EpCam)-positive cells. Loss of c-Met receptor decreased the sphere-forming capacity of oval cells in vitro as well as reduced oval cell pool, impaired migration, and decreased hepatocytic differentiation in vivo, as demonstrated by double immunofluorescence using oval- (A6 and EpCam) and hepatocyte-specific (i.e. hepatocyte nuclear factor 4-alpha) antibodies. Furthermore, lack of c-Met had a profound effect on tissue remodeling and overall composition of HSC niche, which was associated with greatly reduced matrix metalloproteinase (MMP)9 activity and decreased expression of stromal-cell-derived factor 1. Using a combination of double immunofluorescence of cell-type-specific markers with MMP9 and gelatin zymography on the isolated cell populations, we identified macrophages as a major source of MMP9 in DDC-treated livers. The Mx1-Cre-driven c-met deletion caused the greatest phenotypic impact on HSCs response, as compared to the selective inactivation in the epithelial cell lineages achieved in c-Met(fl/fl); Alb-Cre(+/-) mice. However, in both models, genetic loss of c-met triggered a similar cascade of events, leading to the failure of HSC mobilization and death of the mice. Conclusion: These results establish a direct contribution of c-Met in the regulation of HSC response and support a unique role for HGF/c-Met as an essential growth-factor-signaling pathway for regeneration of diseased liver.
Hepatology 11/2011; 55(4):1215-26. · 11.66 Impact Factor
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Jens U Marquardt, Chiara Raggi,
Jesper B Andersen,
Daekwan Seo,
Itzhak Avital,
David Geller,
Yun-Han Lee,
Mitsuteru Kitade,
Agnes Holczbauer,
Matthew C Gillen,
Elizabeth A Conner,
Valentina M Factor,
Snorri S Thorgeirsson
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ABSTRACT: Epigenetic mechanisms play critical roles in stem cell biology by maintaining pluripotency of stem cells and promoting differentiation of more mature derivatives. If similar mechanisms are relevant for the cancer stem cell (CSC) model, then epigenetic modulation might enrich the CSC population, thereby facilitating CSC isolation and rigorous evaluation. To test this hypothesis, primary human cancer cells and liver cancer cell lines were treated with zebularine (ZEB), a potent DNA methyltransferase-1 inhibitor, and putative CSCs were isolated using the side population (SP) approach. The CSC properties of ZEB-treated and untreated subpopulations were tested using standard in vitro and in vivo assays. Whole transcriptome profiling of isolated CSCs was performed to generate CSC signatures. Clinical relevance of the CSC signatures was evaluated in diverse primary human cancers. Epigenetic modulation increased frequency of cells with CSC properties in the SP fraction isolated from human cancer cells as judged by self-renewal, superior tumor-initiating capacity in serial transplantations, and direct cell tracking experiments. Integrative transcriptome analysis revealed common traits enriched for stemness-associated genes, although each individual CSC gene expression signature exhibited activation of different oncogenic pathways (e.g., EGFR, SRC, and MYC). The common CSC signature was associated with malignant progression, which is enriched in poorly differentiated tumors, and was highly predictive of prognosis in liver and other cancers. Conclusion: Epigenetic modulation may provide a tool for prospective isolation and in-depth analysis of CSC. The liver CSC gene signatures are defined by a pernicious interaction of unique oncogene-specific and common stemness traits. These data should facilitate the identifications of therapeutic tools targeting both unique and common features of CSCs.
Hepatology 05/2011; 54(3):1031-42. · 11.66 Impact Factor
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ABSTRACT: Epigenomic changes such as aberrant hypermethylation and subsequent atypical gene silencing are characteristic features of human cancer. Here, we report a comprehensive characterization of epigenomic modulation caused by zebularine, an effective DNA methylation inhibitor, in human liver cancer. Using transcriptomic and epigenomic profiling, we identified a zebularine response signature that classified liver cancer cell lines into two major subtypes with different drug responses. In drug-sensitive cell lines, zebularine caused inhibition of proliferation coupled with increased apoptosis, whereas drug-resistant cell lines showed up-regulation of oncogenic networks (for example, E2F1, MYC, and TNF) that drive liver cancer growth in vitro and in preclinical mouse models. Assessment of zebularine-based therapy in xenograft mouse models demonstrated potent therapeutic effects against tumors established from zebularine-sensitive but not zebularine-resistant liver cancer cells, leading to increased survival and decreased pulmonary metastasis. Integration of the zebularine gene expression and demethylation response signatures allowed differentiation of patients with hepatocellular carcinoma according to their survival and disease recurrence. This integrated signature identified a subclass of patients within the poor-survivor group that is likely to benefit from therapeutic agents that target the cancer epigenome.
Science translational medicine 10/2010; 2(54):54ra77. · 7.80 Impact Factor
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Yun-Han Lee,
Jesper B Andersen,
Ho-Taek Song,
Adam D Judge,
Daekwan Seo,
Tsuyoshi Ishikawa,
Jens U Marquardt,
Mitsuteru Kitade,
Marian E Durkin, Chiara Raggi,
Hyun Goo Woo,
Elizabeth A Conner,
Itzhak Avital,
Ian Maclachlan,
Valentina M Factor,
Snorri S Thorgeirsson
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ABSTRACT: The development of targeted therapeutics for hepatocellular carcinoma (HCC) remains a major challenge. The ubiquitination modulator COP1 regulates p53 activity by ubiquitination and it is frequently overexpressed in human HCC. In this study, we tested the hypothesis that COP1 blockade by short interfering RNA (siRNA)-mediated inhibition could affect the course of HCC progression. The COP1 isoform COP1-1 was selected as the most effective target for siRNAs in terms of growth inhibition and apoptotic induction in several HCC cell lines. Growth inhibition occurred in HCC cells that retained wild-type p53 or expressed mutant p53 (Y220C or R249S), whereas p53-null Hep3B cells were resistant. Microarray expression analysis revealed that the antiproliferative effects of COP1 blockade were driven by a common subset of molecular alterations including a p53-associated functional network. In an orthotopic mouse xenograft model of HCC, systemic delivery of a modified COP1 siRNA by stable nucleic acid-lipid particles suppressed neoplastic growth in liver without unwanted immune responses. Our findings offer a first proof of principle that COP1 can be a promising target for systemic therapy of HCC.
Cancer Research 10/2010; 70(21):8264-9. · 7.86 Impact Factor
