Progenitor cells of the biliary epithelial cell lineage

Stem-like cells have been identified in liver that are able to differentiate in vivo and in culture to biliary epithelial cells (BEC), hepatocytes and oval cells. The growth factors/cytokines and signal pathways required for the differentiation processes are beginning to be evaluated. There is increasing evidence to suggest that these stem-like cells may originate from both the bone marrow population or from a precursor remnant from liver embryogenesis, as they share many of the same markers (CD34, c-kit, CD45). Most recently, it has been shown that a population of progenitor cells can copurify with mesenchymal bone marrow cells and differentiate under specific culture conditions to form both hepatic epithelial and also endothelial cells. The interaction of haemopoietic and mesenchymal stem cells needs further evaluation. The close association of ductular reactive cells and neovessels in end-stage cholestatic liver diseases and the relation to Jagged/Notch signalling pathway may be important in the regulation of stem cells to form both biliary epithelial and endothelial cells.     

牛肝干细胞的分离培养与鉴定

该实验旨在分离牛肝干细胞,培养观察其生长特性,为比较医学研究及开发牛肝脏体外研究工具提供实验基础。实验采用改良的离体两步胶原酶灌流法,结合密度梯度离心分离牛肝干细胞,观察细胞形态及生长特性,并利用免疫荧光染色和PCR对牛肝干细胞相关标志物进行鉴定。实验分离的细胞接种48 h开始贴壁分裂,随后呈集落样生长,表现出干细胞的特性,低密度下培养504 h后细胞呈肝细胞样分化。正常接种密度的细胞可传至P3代,HE染色可见细胞均为单核,核浆比大,呈幼稚低分化状态;免疫荧光染色和PCR结果均显示,该细胞表达甲胎蛋白AFP、上皮细胞黏附蛋白(EpCAM)、造血干/祖细胞表面标志CD34、干细胞因子受体蛋白(c-kit)、细胞角蛋白CK18、CK19。结果表明,该研究分离了一种具有明显干细胞特征,并表达成熟肝细胞和胆管上皮细胞表面标志物的牛肝干细胞。     

Evidence for mesenchymal-epithelial transition associated with mouse hepatic stem cell differentiation

Mesenchymal-epithelial transition events are related to embryonic development, tissue construction, and wound healing. Stem cells are involved in all of these processes, at least in part. However, the direct evidence of mesenchymal-epithelial transition associated with stem cells is unclear. To determine whether mesenchymal-epithelial transition occurs in liver development and/or the differentiation process of hepatic stem cells in vitro, we analyzed a variety of murine liver tissues from embryonic day 11.5 to adults and the colonies derived from hepatic stem/progenitor cells isolated with flow cytometry. The results of gene expression, immunohistochemistry and Western blot showed that as liver develops, the expression of epithelial markers such as Cytokeratin18 and E-cadherin increase, while expression of mesenchymal markers such as vimentin and N-cadherin decreased. On the other hand, in freshly isolated hepatic stem cells, the majority of cells (65.0%) co-express epithelial and mesenchymal markers; this proportion is significantly higher than observed in hematopoietic cells, non-hematopoietic cells and non-stem cell fractions. Likewise, in stem cell-derived colonies cultured over time, upregulation of epithelial genes (Cytokeratin-18 and E-cadherin) occurred simultaneously with downregulation of mesenchymal genes (vimentin and Snail1). Furthermore, in the fetal liver, vimentin-positive cells in the non-hematopoietic fraction had distinct proliferative activity and expressed early the hepatic lineage marker alpha-fetoprotein. CONCLUSION: Hepatic stem cells co-express mesenchymal and epithelial markers; the mesenchymal-epithelial transition occurred in both liver development and differentiation of hepatic stem/progenitor cells in vitro. Besides as a mesenchymal marker, vimentin is a novel indicator for cell proliferative activity and undifferentiated status in liver cells.     

Hepatic lineages isolated from developing rat liver show different ways of maturation

Immunocytochemical analysis revealed that different hepatic cell types exist during liver development: (i). cells co-expressing the stem-cell marker Thy1 and the hepatic lineage marker CK-18 and (ii). cells only expressing CK-18 (hepatoblasts). In this study we separated the different hepatic cells and analyzed gene-expression and phenotype. Fetal rat livers were digested by collagenase solution. OX43- and OX44-positive hematopoietic cells were depleted and Thy1-positive cells were enriched using Magnetic cell sorting. The different cell compartments were analyzed by RT-PCR and immunocytochemistry for Thy1, CK-18, AFP, and albumin. Hepatoblasts expressed albumin at all times and AFP in the early stages. Thy1-enriched cells expressed CK-18 at all times, albumin in the early, and AFP in the late stages. Thy1-positive cells from fetal livers express liver specific genes. The data suggest that Thy1-positive hepatic cells develop towards hepatic stem cells, and hepatoblasts develop towards mature hepatocytes of the adult liver.     

胎肝中肝干细胞的免疫组织化学研究

目的采用免疫组织化学方法显示不同时期人胚胎肝脏的干细胞,分析肝干细胞的形态与分布特点及发育过程中干细胞在肝脏中的迁徙,探讨肝脏的发生发育及肝内干细胞的来源。方法不同发育时期胎儿肝脏,取材、固定、制成石蜡切片,ABC法检测肝干细胞特异性的表面标记物CD34、CK19、C-11和OV6。结果胎肝内汇管区周边界板处有卵圆样细胞表达CD34、C-11、CK19和OV6,阳性细胞紧密排列成管,呈鞘样包绕着早期汇管区,部分包绕着初级汇管区,随着次级汇管区的成熟,卵圆样干细胞逐渐局限于赫令氏管周围;此外,胚胎发育的不同阶段均可见CD34、OV6阳性的单核样细胞分散在肝索、肝血窦之内,多见于汇管区的问充质组织之内,肝血管内鲜见。结论胚胎发育早期汇管区周边界板处含有丰富的干细胞,可能是肝脏发育的起点,这些干细胞逐渐分化为胆管上皮样细胞,然后分化为肝细胞和胆管上皮细胞;造血干细胞是肝内的另一干细胞来源,造血干细胞在肝内受到诱导作用分化为小部分的肝实质细胞。     

胎儿胰岛样细胞团源上皮样细胞分离、纯化和鉴定

旨在优化胰腺干细胞分离、鉴定的方法和体系,为糖尿病研究和治疗提供种子细胞。采用胶原酶消化法,分离培养出胰岛样细胞团(ICCs),对其进行贴壁培养,从中纯化出上皮样细胞。采用MTT法测定其生长情况并绘制生长曲线。采用免疫组织化学染色检测分离得到细胞的PDX-1、PCNA、CK-7、CK-19、Nestin、Glut2、Vimentin、Insulin表达情况。应用流式细胞仪检测其表面标志。由分离培养的ICCs成功纯化出上皮样细胞;传40代,每代冻存106~108个细胞;生长曲线显示其传代第3天进入对数生长期,第5天进入平台期;免疫组织化学染色显示其表达PDX-1、PCNA、CK-7、CK-19、Nestin、Glut2、Vimentin;不表达Insulin;流式细胞仪分析表明其表达CD29、CD44、CD166,不表达CD11a、CD14、CD34、CD45、CD90、CD105、CD117。由胎儿胰腺能分离出具有自我更新能力的上皮样细胞,为导管来源,具干细胞特性。     

Cell turnover in the repopulated rat liver: distinct lineages for hepatocytes and the biliary epithelium

The dynamics of cell renewal in the normal adult liver remains an unresolved issue. We investigate the possible contribution of a common biliary precursor cell pool to hepatocyte turnover in the chimeric long-term repopulated rat liver. The retrorsine (RS)-based model of massive liver repopulation was used. Animals not expressing the CD26 marker (CD26^-) were injected with RS, followed by transplantation of 2 million syngeneic hepatocytes isolated from a normal CD26-expressing donor. Extensive (80-90 %) replacement of resident parenchymal cells was observed at 1 year post-transplantation and persisted at 2 years, as expected. A panel of specific markers, including cytokeratin 7, OV6, EpCAM, claudin 7 and α-fetoprotein, was employed to locate the in situ putative progenitor and/or biliary epithelial cells in the stably repopulated liver. No overlap was observed between any of these markers and the CD26 tag identifying transplanted cells. Exposure to RS was not inhibitory to the putative progenitor and/or biliary epithelial cells, nor did we observe any evidence of cell fusion between these cells and the transplanted cell population. Given the long-term (>2 years) stability of the donor cell phenotype in this model of liver repopulation, the present findings suggest that hepatocyte turnover in the repopulated liver is fuelled by a cell lineage distinct from that of the biliary epithelium and relies largely on the differentiated parenchymal cell population. These results support the solid biological foundation of liver repopulation strategies based on the transplantation of isolated hepatocytes.     

肝干细胞的来源与作用

卵圆细胞(oval cells)是肝脏内体积小、细胞质清澈、核卵圆形、不易定性的细胞。它们可能来源于骨髓或与骨髓有关的细胞群,是活化形式的肝干细胞。肝干细胞的形态特征与卵圆细胞相似,生化标记为c-kit/CD~(45)/TER19。本文总结了人们对肝干细胞的认识和肝干细胞在肝脏发育、肝再生、肝癌发生中的作用及与其它细胞来源的联系。     

CD117 Expression in Fibroblasts-Like Stromal Cells Indicates Unfavorable Clinical Outcomes in Ovarian Carcinoma Patients

The stem cell factor (SCF) receptor CD117 (c-kit), is widely used for identification of hematopoietic stem cells and cancer stem cells. Moreover, CD117 expression in carcinoma cells indicates a poor prognosis in a variety of cancers. However the potential expression in tumor microenvironment and the biological and clinical impact are currently not reported. The expression of CD117 was immunohistochemically evaluated in a serial of 242 epithelial ovarian cancer (EOC) cases. Thirty-eight out of 242 cases were CD117 positive in fibroblast-like stromal cells and 22 cases were positive in EOC cells. Four cases were both positive in fibroblast-like stromal cells and EOC cells for CD117. CD117 expression in fibroblast-like stromal cells in ovarian carcinoma was closely linked to advanced FIGO stage, poor differentiation grade and histological subtype (p<0.05), and it was significantly associated with poor overall survival (OS) and progression free survival (PFS) (Kaplan-Meier analysis; p<0.05, log-rank test). CD117 expression in ovarian carcinoma cells was not associated with these clinicopathological variables. The CD117 positive fibroblast-like stromal cells were all positive for mesenchymal stem/stromal cell (MSC) marker CD73 but negative for fibroblast markers fibroblast activation protein (FAP) and α smooth muscle actin (α-SMA), indicating that the CD117+/CD73+ fibroblast-like stromal cells are a subtype of mesenchymal stem cells in tumor stroma, although further characterization of these cells are needed. It is concluded herewith that the presence of CD117+/CD73+ fibroblast-like stromal cells in ovarian carcinoma is an unfavorable clinical outcome indication.     

Analyses to clarify rich fractions in hepatic progenitor cells from human umbilical cord blood and cell fusion

Umbilical cord blood (UCB) is a source of hematopoietic stem cells and other stem cells, and human UCB cells have been reported to contain transplantable hepatic progenitor cells. However, the fractions of UCB cells in which hepatic progenitor cells are rich remain to be clarified. In the present study, first, the fractionated cells by CD34, CD38, and c-kit were transplanted via portal vein of NOD/SCID mice, and albumin mRNA expression was examined in livers at 1 and 3 months posttransplantation. At 1 and 3 months, albumin mRNA expression in CD34+UCB cells-transplanted livers was higher than that in CD34- cells-transplanted livers. Albumin mRNA expression in CD34+CD38+ cells-transplanted livers was higher than that in CD34+CD38- cells-transplanted [corrected] liver at 1 month. However, it was much higher [corrected] in CD34+CD38- cell-transplanted livers at 3 months. Similar expression of albumin mRNA was obtained between CD34+CD38+c-kit+ cells- and CD34+CD38-c-kit- cells-transplanted livers, and between CD34+CD38-c-kit+ cells- and CD34+CD38-c-kit- cells-transplanted livers, respectively. Second, fluorescence in situ hybridization and immunohistochemistry were performed to examine whether UCB cells really transdifferentiated into hepatocytes or they only fused with mouse hepatocytes. In mouse liver sections, of 1.2% cells which had human chromosomes, 0.9% cells were due to cell fusion, whereas 0.3% cells were transdifferentiated into human hepatocytes. These results suggest that CD34+UCB cells are rich fractions in hepatic progenitor cells, and that transdifferentiation from UCB cells into hepatocytes as well as cell fusion simultaneously occur in this situation.     

Wnt impacts growth and differentiation in ex vivo liver development

The Wnt-beta-catenin pathway plays a role in liver growth and development. Here, we investigate the direct effect of Wnt-3A on ex vivo liver development. Livers from mouse embryos at day 10 were cultured in serum-free Wnt-3A-conditioned media alone or with HGF and insulin for 72 h and analyzed for histology, proliferation, apoptosis and lineage. Control cultures grown in serum-free conditions or Wnt-3A and sFRP-1 combination display loss of architecture and proliferation and increased apoptosis. In the presence of Wnt-3A, embryonic liver cultures show CK-19-positive cells (biliary phenotype) displaying proliferation, minimal apoptosis and duct-like histological arrangement. HGF and Wnt combination exhibited normal histology as seen in the presence of 10% serum displaying stem cells, hepatocytes and primitive bile ducts. HGF, insulin and Wnt combination provided no additional benefits rather had an overall deleterious effect. Thus, Wnt supports biliary differentiation by enhancing stem cell specification, hepatocyte trans-differentiation and promoting biliary survival. HGF and Wnt combination supports stem cells, hepatocytes and bile ducts. The addition of insulin to the combination of HGF and Wnt provided no growth or differentiation advantage. Our results indicate usefulness of Wnt and HGF in hepatocyte cultures and suggest their balance during normal liver development.     

Cytokeratin expression in human cell lines derived from liver tumors.

Immunohistochemical staining of cell lines derived from human liver tumours showed that five cell lines derived from hepatocellular carcinoma (HCC) and hepatoblastoma were stained positively with monoclonal keratin antibodies, CK-5 (Ker-18-specific) and KL-1 (broad specificity), but not with CK-7 (Ker-7-specific). On the other hand, four carcinoma cell lines derived from the biliary system were stained positively with not only CK-5 and KL-1, but also CK-7.     

Molecular cloning of murine STAP-1, the stem-cell-specific adaptor protein containing PH and SH2 domains

To identify the novel substrate of c-kit which is important for hematopoietic stem cell self-renewal or differentiation, CD34-low/negative, Sca-1-positive, c-kit-positive, and lineage marker-negative (CD34(low/-)Sca-1(+)c-kit(+)Lin(-)) cells were sorted by a fluorescence-activated cell sorter from mouse bone marrow cells and a yeast two-hybrid cDNA library was constructed. By screening with c-kit as bait, we cloned a novel cDNA, designed STAP-1, encoding an adaptor protein with a Pleckstrin homology domain, the Src homology 2 (SH2) domain, and a number of tyrosine phosphorylation sites. RT-PCR analysis revealed that STAP-1 expression is restricted in the bone marrow cell fraction expressing c-kit. The highest expression was observed in the CD34(low/-)Sca-1(+)c-kit(+)Lin(-) stem cell-enriched fraction. The murine myeloid cell line, M1, expressed a high level of STAP-1. However, the expression was strongly repressed in response to leukemia inhibitory factor (LIF) which induced monocytic differentiation of M1 cells, suggesting that STAP-1 is associated with the undifferentiated cell type. A two-hybrid assay indicated that STAP-1 bound not only to c-kit but also to c-fms but not to JAK2 or Pyk2. In 293 cells, STAP-1 was tyrosine-phosphorylated by activated c-kit. An in vitro binding assay suggested that the STAP-1 SH2 domain interacted with several tyrosine-phosphorylated proteins including c-kit and STAT5. These suggest that STAP-1 functions as an adaptor molecule downstream of c-kit in hematopoietic stem cells.     

Fetal and adult liver stem cells for liver regeneration and tissue engineering

For the development of innovative cell-based liver directed therapies, e.g. liver tissue engineering, the use of stem cells might be very attractive to overcome the limitation of donor liver tissue. Liver specific differentiation of embryonic, fetal or adult stem cells is currently under investigation. Different types of fetal liver (stem) cells during development were identified, and their advantageous growth potential and bipotential differentiation capacity were shown. However, ethical and legal issues have to be addressed before using fetal cells. Use of adult stem cells is clinically established, e.g. transplantation of hematopoietic stem cells. Other bone marrow derived liver stem cells might be mesenchymal stem cells (MSC). However, the transdifferentiation potential is still in question due to the observation of cellular fusion in several in vivo experiments. In vitro experiments revealed a crucial role of the environment (e.g. growth factors and extracellular matrix) for specific differentiation of stem cells. Co-cultured liver cells also seemed to be important for hepatic gene expression of MSC. For successful liver cell transplantation, a novel approach of tissue engineering by orthotopic transplantation of gel-immobilized cells could be promising, providing optimal environment for the injected cells. Moreover, an orthotopic tissue engineering approach using bipotential stem cells could lead to a repopulation of the recipients liver with healthy liver and biliary cells, thus providing both hepatic functions and biliary excretion. Future studies have to investigate, which stem cell and environmental conditions would be most suitable for the use of stem cells for liver regeneration or tissue engineering approaches.     

胎肝干细胞的分离、培养与鉴定

目的体外扩增培养大鼠胎肝干细胞,研究其形态、生物学特性及表面标志物,探讨胎肝干细胞的性质。方法分离培养胎龄12-16d的胎肝细胞,SABC法检测原代、传代后及细胞克隆中的肝干细胞特异表面标志物OV-6、CK-19及nestin的表达。结果原代、传代培养的胎肝细胞部分表达OV-6、CK-19及nestin;培养3d开始出现小细胞团,1个月即形成肉眼可见的细胞集落,5-7d传代一次;细胞克隆几乎全部为干细胞标志阳性细胞。结论胎肝干细胞可通过克隆筛选法进行体外扩增,胎肝内存在nestin阳性干细胞,可能是一种更为原始的干细胞,在胚胎发育中起重要作用。     

Stem cells, cell transplantation and liver repopulation

Liver transplantation is currently the only therapeutic option for patients with end-stage chronic liver disease and for severe acute liver failure. Because of limited donor availability, attention has been focused on the possibility to restore liver mass and function through cell transplantation. Stem cells are a promising source for liver repopulation after cell transplantation, but whether or not the adult mammalian liver contains hepatic stem cells is highly controversial. Part of the problem is that proliferation of mature adult hepatocytes is sufficient to regenerate the liver after two-thirds partial hepatectomy or acute toxic liver injury and participation of stem cells is not required. However, under conditions in which hepatocyte proliferation is blocked, undifferentiated epithelial cells in the periportal areas, called "oval cells", proliferate, differentiate into hepatocytes and restore liver mass. These cells are referred to as facultative liver stem cells, but they do not repopulate the normal liver after their transplantation. In contrast, epithelial cells isolated from the early fetal liver can effectively repopulate the normal liver, but they are already traversing the hepatic lineage and may not be true stem cells. Mesenchymal stem cells and embryonic stem cells can be induced to differentiate along the hepatic lineage in culture, but at present these cells are inefficient in repopulating the liver. This review will characterize these various cell types and compare the properties of these cells and the conditions under which they do or do not repopulate the liver following their transplantation.     

The promise of stem cell markers in the diagnosis and therapy of epithelial dysplasia and oral squamous cell carcinoma

Oral squamous cell carcinoma (OSCC) is the most common type of head and neck cancer. Epithelial dysplasia is often initiated in the cells and cell nuclei adjacent to the epithelial cell membrane. Reduced cell–cell adhesions enable cancer cells to detach from the tumor and disseminate to other organs. The mutations in epithelial dysplasia markers such as E‐cadherin and epithelial cell adhesion molecules (CD326) can lead to proliferation, growth and survival of the tumor cells and persistence of numerous malignancies that play a key role in epithelial dysplasia of OSCC. Accordingly, these genes can be considered prognostic markers or potential therapeutic targets for the tailored management of patients with OSCC. The gene expression profile of OSCC stem cells indicates a differential pattern that facilitates establishing a cell signature. Owing to the highly tumorigenic behavior of cancer stem cells and the role of these cells in tumor differentiation, treatment resistance, relapse, and metastasis, we reviewed the role of stem cell markers in epithelial dysplasia and OSCC.     

Hepatic progenitor cells in human fetal liver express the oval cell marker Thy-1

Hepatic progenitor cells play a major role in regenerating diseased liver. In rodents, progenitors forming hepatocytes or cholangiocytes are identified by the stem cell marker Thy-1. The aim of this study was to ascertain whether progenitor cells expressing Thy-1 could be identified in human fetal liver. Midtrimester human fetal liver was immunostained for Thy-1, cytokeratins 18 and 19, vimentin, CD34, CD45, and fibrinogen. Thy-1+ and Thy-1+CD34+ populations were purified using fluorescence-activated cell sorting (FACS). Immunofluorescence and mRNA expression were used to examine the bipotential nature of purified stem cells. We found that Thy-1+ cells were concentrated in portal tracts but were also scattered in parenchyma. In FACS-prepared cells, 0.18-3.08% (median 0.65%, n = 14) of cells were Thy-1+. Immunophenotyping revealed that some Thy-1+ cells coexpressed cytokeratins 18 and 19, others, fibrinogen and cytokeratin 19. RT-PCR demonstrated that Thy-1+ cells expressed mRNA for Thy-1, cytokeratin 18, and cytokeratin 19, and Thy-1+CD34+ cells expressed mRNA for alpha-fetoprotein, transferrin, and hepatocyte nuclear factor-4alpha. Thy-1+ cells were identified in fetal liver. These cells expressed several lineage markers, including coexpression of biliary and hepatocellular proteins and mRNA. These data suggest that Thy-1 is a marker of liver stem cells in human fetal liver.