Inhibitory effects of microRNA 19b in hepatic stellate cell-mediated fibrogenesis

Hepatic stellate cell (HSC) activation is a pivotal event in initiation and progression of hepatic fibrosis and a major contributor to collagen deposition driven by transforming growth factor beta (TGF-β). MicroRNAs (miRs), small noncoding RNAs modulating messenger RNA (mRNA) and protein expression, have emerged as key regulatory molecules in chronic liver disease. We investigated differentially expressed miRs in quiescent and activated HSCs to identify novel regulators of profibrotic TGF-β signaling. miR microarray analysis was performed on quiescent and activated rat HSCs. Members of the miR-17-92 cluster (19a, 19b, 92a) were significantly down-regulated in activated HSCs. Because miR 19b showed the highest fold-change of the cluster members, activated HSCs were transfected with miR 19b mimic or negative control and TGF-β signaling and HSC activation assessed. miR 19b expression was determined in fibrotic rat and human liver specimens. miR 19b mimic negatively regulated TGF-β signaling components demonstrated by decreased TGF-β receptor II (TGF-βRII) and SMAD3 expression. Computational prediction of miR 19b binding to the 3' untranslated region of TGF-βRII was validated by luciferase reporter assay. Inhibition of TGF-β signaling by miR 19b was confirmed by decreased expression of type I collagen and by blocking TGF-β-induced expression of α1(I) and α2(I) procollagen mRNAs. miR 19b blunted the activated HSC phenotype by morphological assessment and decreased smooth muscle α-actin expression. Additionally, miR 19b expression was markedly diminished in fibrotic rat liver compared with normal liver; similarly, miR 19b expression was markedly down-regulated in fibrotic compared with normal human livers. CONCLUSION: miR 19b is a novel regulator of TGF-β signaling in HSCs, suggesting a potential therapeutic approach for hepatic fibrosis.     

Up‐regulation of breast cancer resistance protein expression in hepatoblastoma following chemotherapy: A study in patients and in vitro

Aim: Hepatoblastoma (HB), the most common pediatric malignant liver tumor, is treated with chemotherapy to facilitate surgical resection. Previous studies suggest that HB acquires chemoresistance via increased expression of multidrug resistance protein 1 (MDR1, ABCC1). There is no well established evidence that this also occurs in the clinical setting and little is known about the effects of chemotherapeutic treatments on HB in situ. Methods: Clinical and histopathological features and expression patterns of ABC transporters in diagnostic needle biopsies from 7 HBs taken before chemotherapy were compared with those in surgically resected tumors. To understand the mechanism s leading to chemoresistance we also investigated the involvement of hypoxia on protein expression and functional activity of drug transporters (BCRP and MDR1) in cultures of HepG2 human HB cells. Results: We found that chemotherapeutical treatment of HBs led to an increased expression of the breast cancer resistance protein (BCRP, ABCG2) in all patients studied. There was no change in the expression pattern of MDR1 or other ABC transporters. Chemotherapy‐induced specific vascular abnormalities associated with areas of necrosis and fibrosis were seen in all cases, suggesting tumor hypoxia. The observations of increased BCRP expression in hypoxic areas of three‐dimensional HepG2 aggregates and the enhanced BCRP function in monolayer cultures of HepG2 cells under hypoxic conditions, support a role for hypoxia in enhanced BCRP expression. Conclusions: Chemotherapeutical treatment of HB leads to vascular alterations that modify the tumor microenvironment, and increased BCRP expression in which hypoxia might play a role. No evidence was found for upregulation of MDR1 in HBs as suggested from previous experimental studies.     

Genome-wide miRNA profiling of mantle cell lymphoma reveals a distinct subgroup with poor prognosis

miRNA deregulation has been implicated in the pathogenesis of mantle cell lymphoma (MCL). Using a high-throughput quantitative real-time PCR platform, we performed miRNA profiling on cyclin D1-positive MCL (n = 30) and cyclin D1-negative MCL (n = 7) and compared them with small lymphocytic leukemia/lymphoma (n = 12), aggressive B-cell lymphomas (n = 138), normal B-cell subsets, and stromal cells. We identified a 19-miRNA classifier that included 6 up-regulated miRNAs and 13 down regulated miRNA that was able to distinguish MCL from other aggressive lymphomas. Some of the up-regulated miRNAs are highly expressed in naive B cells. This miRNA classifier showed consistent results in formalin-fixed paraffin-embedded tissues and was able to distinguish cyclin D1-negative MCL from other lymphomas. A 26-miRNA classifier could distinguish MCL from small lymphocytic leukemia/lymphoma, dominated by 23 up-regulated miRNAs in MCL. Unsupervised hierarchical clustering of MCL patients demonstrated a cluster characterized by high expression of miRNAs from the polycistronic miR17-92 cluster and its paralogs, miR-106a-363 and miR-106b-25, and associated with high proliferation gene signature. The other clusters showed enrichment of stroma-associated miRNAs, and also had higher expression of stroma-associated genes. Our clinical outcome analysis in the present study suggested that miRNAs can serve as prognosticators.     

Comparison of hepatic properties and transplantation of Thy-1(+) and Thy-1(-) cells isolated from embryonic day 14 rat fetal liver

Thy-1, a marker of hematopoietic progenitor cells, is also expressed in activated oval cells of rat liver. Thy-1(+) cells are also in rat fetal liver and exhibit properties of bipotent hepatic epithelial progenitor cells in culture. However, no information is available concerning liver repopulation by Thy-1(+) fetal liver cells. Therefore, we isolated Thy-1(+) and Thy-1(-) cells from embryonic day (ED) 14 fetal liver and compared their gene expression characteristics in vitro and proliferative and differentiation potential after transplantation into adult rat liver. Fetal liver cells selected for Thy-1 expression using immunomagnetic microbeads were enriched from 5.2%-87.2% Thy-1(+). The vast majority of alpha fetoprotein(+), albumin(+), cytokine-19(+), and E-cadherin(+) cells were found in cultured Thy-1(-) cells, whereas nearly all CD45(+) cells were in the Thy-1(+) fraction. In normal rat liver, transplanted Thy-1(+) cells produced only rare, small DPPIV(+) cell clusters, very few of which exhibited a hepatocytic phenotype. In retrorsine-treated liver, transplanted Thy-1(+) fetal liver cells achieved a 4.6%-23.5% repopulation. In contrast, Thy-1(-) fetal liver cells substantially repopulated normal adult liver and totally repopulated retrorsine-treated liver. Regarding the stromal cell-derived factor (SDF)-1/chemokine (C-X-C motif) receptor 4 (CXCR4) axis for stem cell homing, Thy-1(+) and Thy-1(-) fetal hepatic epithelial cells equally expressed CXCR4. However, SDF-1alpha expression was augmented in bile ducts and oval cells in retrorsine/partial hepatectomy-treated liver, and this correlated with liver repopulation by Thy-1(+) cells. CONCLUSION: Highly enriched Thy-1(+) ED14 fetal liver cells proliferate and repopulate the liver only after extensive liver injury and represent a fetal hepatic progenitor cell population distinct from Thy-1(-) stem/progenitor cells, which repopulate the normal adult liver.     

Gene expression pattern in hepatic stem/progenitor cells during rat fetal development using complementary DNA microarrays

To identify new and differentially expressed genes in rat fetal liver epithelial stem/progenitor cells during their proliferation, lineage commitment, and differentiation, we used a high throughput method-mouse complementary DNA (cDNA) microarrays-for analysis of gene expression. The gene expression pattern of rat hepatic cells was studied during their differentiation in vivo: from embryonic day (ED) 13 until adulthood. The differentially regulated genes were grouped into two clusters: a cluster of up-regulated genes comprised of 281 clones and a cluster of down-regulated genes comprised of 230 members. The expression of the latter increased abruptly between ED 16 and ED 17. Many of the overexpressed genes from the first cluster fall into distinct, differentially expressed functional groups: genes related to development, morphogenesis, and differentiation; calcium- and phospholipid-binding proteins and signal transducers; and cell adhesion, migration, and matrix proteins. Several other functional groups of genes that are initially down-regulated, then increase during development, also emerged: genes related to inflammation, blood coagulation, detoxification, serum proteins, amino acids, lipids, and carbohydrate metabolism. Twenty-eight genes overexpressed in fetal liver that were not detected in adult liver are suggested as potential markers for identification of liver progenitor cells. In conclusion, our data show that the gene expression program of fetal hepatoblasts differs profoundly from that of adult hepatocytes and that it is regulated in a specific manner with a major switch at ED 16 to 17, marking a dramatic change in the gene expression program during the transition of fetal liver progenitor cells from an undifferentiated to a differentiated state. Supplementary material for this article can be found on the HEPATOLOGY website (http://interscience.wiley.com/jpages/0270-9139/suppmat/index.html).     

Genetic screen identifies microRNA cluster 99b/let-7e/125a as a regulator of primitive hematopoietic cells

Hematopoietic stem/progenitor cell (HSPC) traits differ between genetically distinct mouse strains. For example, DBA/2 mice have a higher HSPC frequency compared with C57BL/6 mice. We performed a genetic screen for micro-RNAs that are differentially expressed between LSK, LS(-)K(+), erythroid and myeloid cells isolated from C57BL/6 and DBA/2 mice. This analysis identified 131 micro-RNAs that were differentially expressed between cell types and 15 that were differentially expressed between mouse strains. Of special interest was an evolutionary conserved miR cluster located on chromosome 17 consisting of miR-99b, let-7e, and miR-125a. All cluster members were most highly expressed in LSKs and down-regulated upon differentiation. In addition, these microRNAs were higher expressed in DBA/2 cells compared with C57BL/6 cells, and thus correlated with HSPC frequency. To functionally characterize these microRNAs, we overexpressed the entire miR-cluster 99b/let-7e/125a and miR-125a alone in BM cells from C57BL/6 mice. Overexpression of the miR-cluster or miR-125a dramatically increased day-35 CAFC activity and caused severe hematopoietic phenotypes upon transplantation. We showed that a single member of the miR-cluster, namely miR-125a, is responsible for the majority of the observed miR-cluster overexpression effects. Finally, we performed genome-wide gene expression arrays and identified candidate target genes through which miR-125a may modulate HSPC fate.     

Salivary gland progenitor cells induced by duct ligation differentiate into hepatic and pancreatic lineages

Tissue damage can be assessed based on regenerative responses, including progenitor cell proliferation. In the salivary gland, tissue damage induced by ligation of main ducts leads to the disappearance of acinar cells and to marked proliferation of ductal cells. Reopening of the ducts leads to repopulation of acinar cells within 1 to 2 weeks, which suggests activation of tissue progenitor cells in a damaged state. Because submandibular glands derive from the endoderm and ectoderm, we investigated the possibility of the presence of endodermal progenitor cells. We cultured cells obtained from the ligated salivary gland and identified colonies of epithelium-like cells. We singled out and purified the cells by limited dilution, and one of the cells designated SGP-1 was used for further experiments. The SGP-1 expresses both alpha6beta1 integrin and cytoplasmic laminin. The hematopoietic stem cell marker CD34 and hepatic oval cell markers such as albumin, alpha-fetoprotein (AFP), and cytokeratin 19 are all negative. However, when SGP-1 cells were transplanted into the liver via the portal vein, these cells were integrated into hepatic trabecula and produced albumin. When SGP-1 cells formed clusters on type I collagen-coated dishes, they differentiated into endodermal lineage and 2 major types of clusters appeared: one contained cells positive for AFP and/or albumin (hepatic cluster) and the other positive for glucagon and/or insulin (pancreatic cluster). On laminin-coated dishes, SGP-1 selectively differentiated into hepatic-type cells. In conclusion, the multipotent progenitor cells isolated from the rat salivary gland have characteristics of tissue stem cells and can differentiate into cells of endodermal lineages.     

Stem and progenitor cell systems in liver development and regeneration

The liver comprises two stem/progenitor cell systems: fetal and adult liver stem/progenitor cells. Fetal hepatic progenitor cells, derived from foregut endoderm, differentiate into mature hepatocytes and cholangiocytes during liver development. Adult hepatic progenitor cells contribute to regeneration after severe and chronic liver injuries. However, the characteristics of these somatic hepatic stem/progenitor cells remain unknown. Culture systems that can be used to analyze these cells were recently established and hepatic stem/progenitor cell‐specific surface markers including delta‐like 1 homolog (DLK), cluster of differentiation (CD) 13, CD133, and LIV2 were identified. Cells purified using antibodies against these markers proliferate for an extended period and differentiate into mature cells both in vitro and in vivo. Methods to force the differentiation of human embryonic stem and induced pluripotent stem (iPS) cells into hepatic progenitor cells have been recently established. We demonstrated that the CD13⁺CD133⁺ fraction of human iPS‐derived cells contained numerous hepatic progenitor‐like cells. These analyses of hepatic stem/progenitor cells derived from somatic tissues and pluripotent stem cells will contribute to the development of new therapies for severe liver diseases.     

miR-194 is a marker of hepatic epithelial cells and suppresses metastasis of liver cancer cells in mice

MicroRNAs (miRNAs) are small noncoding RNAs that regulate gene expression by interacting with the 3' untranslated region (3'-UTR) of multiple mRNAs. Recent studies have linked miRNAs to the development of cancer metastasis. In this study, we show that miR-194 is specifically expressed in the human gastrointestinal tract and kidney. Moreover, miR-194 is highly expressed in hepatic epithelial cells, but not in Kupffer cells or hepatic stellate cells, two types of mesenchymal cells in the liver. miR-194 expression was decreased in hepatocytes cultured in vitro, which had undergone a dedifferentiation process. Furthermore, expression of miR-194 was low in liver mesenchymal-like cancer cell lines. The overexpression of miR-194 in liver mesenchymal-like cancer cells reduced the expression of the mesenchymal cell marker N-cadherin and suppressed invasion and migration of the mesenchymal-like cancer cells both in vitro and in vivo. We further demonstrated that miR-194 targeted the 3'-UTRs of several genes that were involved in epithelial-mesenchymal transition and cancer metastasis. Conclusion: These results support a role of miR-194, which is specifically expressed in liver parenchymal cells, in preventing liver cancer cell metastasis.     

Novel hepatic progenitor cell surface markers in the adult rat liver

Hepatic progenitor/oval cells appear in injured livers when hepatocyte proliferation is impaired. These cells can differentiate into hepatocytes and cholangiocytes and could be useful for cell and gene therapy applications. In this work, we studied progenitor/oval cell surface markers in the liver of rats subjected to 2-acetylaminofluorene treatment followed by partial hepatectomy (2-AAF/PH) by using rat genome 230 2.0 Array chips and subsequent RT-PCR, immunofluorescent (IF), immunohistochemical (IHC) and in situ hybridization (ISH) analyses. We also studied expression of the identified novel cell surface markers in fetal rat liver progenitor cells and FAO-1 hepatoma cells. Novel cell surface markers in adult progenitor cells included tight junction proteins, integrins, cadherins, cell adhesion molecules, receptors, membrane channels and other transmembrane proteins. From the panel of 21 cell surface markers, 9 were overexpressed in fetal progenitor cells, 6 in FAO-1 cells and 6 are unique for the adult progenitors (CD133, claudin-7, cadherin 22, mucin-1, ros-1, Gabrp). The specificity of progenitor/oval cell surface markers was confirmed by ISH and double IF analyses. Moreover, study of progenitor cells purified with Ep-CAM antibodies from D-galactosamine injured rat liver, a noncarcinogenic model of progenitor cell activation, verified that progenitor cells expressed these markers. CONCLUSION: We identified novel cell surface markers specific for hepatic progenitor/oval cells, which offers powerful tool for their identification, isolation and studies of their physiology and pathophysiology. Our studies also reveal the mesenchymal/epithelial phenotype of these cells and the existence of species diversity in the hepatic progenitor cell identity.     

miR-106b-25基因簇在肝泡型包虫病肝组织中的表达及意义

目的 检测肝泡型包虫病肝组织中miR-106b-25基因簇(miR-106b、miR-93、miR-25)的表达水平,分析3者在肝纤维化进程中的作用及其相互关系。方法 将20例经手术治疗的肝泡型包虫病肝组织匹配后分为病灶旁肝组织和正常肝组织,RT-PCR技术检测miR-106b-25基因簇的表达水平。HE和Masson染色观察病理变化与纤维化程度。结果 病灶旁肝组织纤维化程度高于正常肝组织;miR-106b-25基因簇在病灶旁肝组织的表达量均高于正常肝组织;miR-106b-25基因簇表达量与肝纤维化程度呈正相关;随着纤维化程度加重,miR-106b-25基因簇各成员的表达量也增加;3种miRNA之间表达呈正相关。结论 泡型包虫病病灶旁肝组织比正常肝组织纤维化程度严重,miR-106b-25基因簇参与肝泡型包虫病致肝纤维化。     

Immortalized p19ARF null hepatocytes restore liver injury and generate hepatic progenitors after transplantation

Primary hepatocytes are blocked in mitotic activity and well-defined culture conditions only allow the limited expansion of these cells. Various genetic modifications have therefore been employed to establish immortalized hepatic cell lines, but, unfortunately, proper hepatocyte cultures conducting a faithful hepatic gene expression program and lacking malignancy are hardly available. Here we report the immortalization of primary hepatocytes isolated from p19(ARF) null mice using the rationale that loss of p19(ARF) lowers growth-suppressive functions of p53 and bypasses cellular senescence without losing genetic stability. The established hepatocytes, called MIM, express liver-specific markers, show a nontumorigenic phenotype, and competence to undergo Fas-mediated apoptosis. Intrasplenic transplantation of GFP-expressing parental MIM cells into Fas-injured livers of SCID mice revealed liver-reconstituting activity. In the regenerated liver, MIM cells localized in small-sized clusters and showed presence in structures comparable to canals of Hering, the site of oval cells. Transplantation of MIM-Bcl-X(L) cells, which are protected against apoptosis, and successive Fas-induced liver damage, enhanced donor-derived liver repopulation by showing differentiation into cholangiocytes and cells expressing markers characteristic of both fetal hepatocytes and oval cells. In conclusion, these data indicate that long-term cultivated p19(ARF) null hepatocytes are capable of generating hepatic progenitor cells during liver restoration, and thus represent a highly valuable tool to study the differentiation repertoire of hepatocytes.     

Orchestration of hepatocellular carcinoma development by diverse liver cancer stem cells

Hepatocellular carcinoma (HCC) is one of the world’s most aggressive diseases and carries a poor prognosis for patients. Recent evidence suggests that HCC is organized by cancer stem cells (CSCs), which are a subset of cells with stem cell-like features. CSCs are considered a pivotal target for the eradication of cancer, and liver CSCs have been investigated using various stem cell markers. Several hepatic stem/progenitor markers have been shown to be useful for isolating putative CSCs from HCC, although the expression patterns and phenotypic diversity of CSCs purified by these markers remain obscure. Recently, we found that liver CSCs defined by different markers show unique features of tumorigenicity and metastasis, with phenotypes closely associated with committed liver lineages. Furthermore, our data suggest that these distinct CSCs collaborate to orchestrate the tumorigenicity and metastasis of HCC. In this review article, we summarize the recent advances in understanding the pathogenesis and heterogeneity of liver CSCs.