EpCAM and its potential role in tumor-initiating cells

Epithelial cell adhesion molecule EpCAM is expressed on a subset of normal epithelia and overexpressed on malignant cells from a variety of different tumor entities. This overexpression is even more pronounced on so-called tumor-initiating cells (TICs) of many carcinomas. Taking this rather ubiquitous expression of EpCAM in carcinomas and TICs into account, the question arises how EpCAM can serve as a reliable marker for tumor-initiating cells and what might be the advantage for TICs to express this molecule. Furthermore, several approaches for therapeutic strategies targeting exclusively EpCAM on cancer cells were undertaken over the past decades and have recently been transferred to pre-clinical attempts to eradicate TICs. In the present review, we will depict potential functions of EpCAM in tumor cells with a special focus on TICs and therapeutic implications.     

EpCAM and its potential role in tumor-initiating cells

Epithelial cell adhesion molecule EpCAM is expressed on a subset of normal epithelia and overexpressed on malignant cells from a variety of different tumor entities. This overexpression is even more pronounced on so-called tumor-initiating cells (TICs) of many carcinomas. Taking this rather ubiquitous expression of EpCAM in carcinomas and TICs into account, the question arises how EpCAM can serve as a reliable marker for tumor-initiating cells and what might be the advantage for TICs to express this molecule. Furthermore, several approaches for therapeutic strategies targeting exclusively EpCAM on cancer cells were undertaken over the past decades and have recently been transferred to pre-clinical attempts to eradicate TICs. In the present review, we will depict potential functions of EpCAM in tumor cells with a special focus on TICs and therapeutic implications.     

EpCAM aptamer mediated cancer cell specific delivery of EpCAM siRNA using polymeric nanocomplex

Background

Epithelial cell adhesion molecule (EpCAM) is overexpressed in solid tumors and regarded as a putative cancer stem cell marker. Here, we report that employing EpCAM aptamer (EpApt) and EpCAM siRNA (SiEp) dual approach, for the targeted delivery of siRNA to EpCAM positive cancer cells, efficiently inhibits cancer cell proliferation.

Results

Targeted delivery of siRNA using polyethyleneimine is one of the efficient methods for gene delivery, and thus, we developed a novel aptamer-PEI-siRNA nanocomplex for EpCAM targeting. PEI nanocomplex synthesized with EpCAM aptamer (EpApt) and EpCAM siRNA (SiEp) showed 198 nm diameter sized particles by dynamic light scattering, spherical shaped particles, of 151 ± 11 nm size by TEM. The surface charge of the nanoparticles was −30.0 mV using zeta potential measurements. Gel retardation assay confirmed the PEI-EpApt-SiEp nanoparticles formation. The difference in size observed by DLS and TEM could be due to coating of aptamer and siRNA on PEI nanocore. Flow cytometry analysis revealed that PEI-EpApt-SiEp has superior binding to cancer cells compared to EpApt or scramble aptamer (ScrApt) or PEI-ScrApt-SiEp. PEI-EpApt-SiEp downregulated EpCAM and inhibited selectively the cell proliferation of MCF-7 and WERI-Rb1 cells.

Conclusions

The PEI nanocomplex fabricated with EpApt and siEp was able to target EpCAM tumor cells, deliver the siRNA and silence the target gene. This nanocomplex exhibited decreased cell proliferation than the scrambled aptamer loaded nanocomplex in the EpCAM expressing cancer cells and may have potential for EpCAM targeting in vivo.

Electronic supplementary material

The online version of this article (doi:10.1186/s12929-014-0108-9) contains supplementary material, which is available to authorized users.     

EpCAM蛋白的表达、纯化及其单克隆抗体的制备

目的:原核表达EpCAM蛋白并制备抗EpCAM特异性单克隆抗体,初步鉴定相应单克隆抗体的特性。方法:PCR扩增EpCAM基因胞外区,将目的基因亚克隆至载体pET-28a(+),转化至大肠埃希菌株BL21,IPTG诱导表达,组氨酸亲和层析法纯化表达产物。纯化蛋白免疫BALB/c小鼠,将成功免疫的小鼠脾细胞与骨髓瘤SP2/0细胞融合,经ELISA筛选得到分泌特异性抗EpCAM的单克隆抗体的细胞株,免疫BALB/c小鼠进一步制备相应的单克隆抗体,并通过Western blot(蛋白质印记)和FACS(流式细胞分析)鉴定单抗的特异性及生物学活性。结果:成功构建重组表达载体pET28a-EpCAM并在大肠杆菌中获得表达,经His-tag亲和层析法获得纯化的EpCAM重组蛋白。EpCAM重组蛋白免疫的BALB/c小鼠的脾细胞与SP2/0细胞融合、筛选,获得两株稳定分泌EpCAM抗体的杂交瘤细胞株,分别命名为4B2、2F2并免疫BALB/c小鼠获得相应的单克隆抗体。Western blot结果显示4B2腹水纯化所得单抗能够识别FaDu细胞系(人咽鳞癌细胞)中的EpCAM蛋白,但2F2未能识别FaDu细胞中的变性的EpCAM蛋白。FACS结果显示两者均能和FaDu细胞中天然的EpCAM蛋白结合。讨论:成功制备了抗EpCAM的单克隆抗体,并能够识别人咽鳞癌细胞系FaDu中表达的EpCAM,为进一步研究EpCAM抗体在肿瘤治疗中的作用提供基础。     

EpCAM expression in the prostate cancer makes the difference in the response to growth factors

Introduction

Epithelial cell adhesion molecule (EpCAM) is expressed in tumors with an epithelial cell of origin, in a heterogeneous manner. Prostate cancer stem-like cells highly express EpCAM. However, little is known about how EpCAM is involved in the ability of cells to adapt to micro-environmental changes in available growth factors, which is one of the essential biological phenotypes of cancer stem-like cells (CSCs).

Methods

EpCAM-high and EpCAM-low subpopulations of cells were established from the prostate cancer cell line PC-3. Signal transductions in response to serum starvation, and on the exposure to EGF ligand or the specific inhibitor were analyzed in terms. Furthermore, we analyzed the expression level of amino acid transporters which contribute to the activation of mTOR signal between the two subgroups.

Results

EpCAM-high and EpCAM-low PC-3 subpopulations showed markedly different responses to serum starvation. EpCAM expression was positively correlated with activation of the mTOR and epithelial growth factor receptor (EGFR) signaling pathways. Furthermore, AMP-activated protein kinase (AMPK) was gradually de-activated in EpCAM-low PC-3 cells in the absence of serum.

Conclusions

EpCAM regulates the AMPK signaling pathway, essential for the response to growth factors characterized by EGF. LAT1, the amino acid transporter stabilized at the cellular membrane by EpCAM, is likely to be responsible for the difference in the susceptibility to EGF between EpCAM-high and EpCAM-low PC-3 cells.     

EpCAM proteolysis: new fragments with distinct functions?

EpCAM [epithelial cell adhesion molecule; CD326 (cluster of differentiation 326)] is highly expressed on epithelium-derived tumours and can play a role in cell proliferation. Recently, RIP (regulated intramembrane proteolysis) has been implicated as the trigger for EpCAM-mediated proliferative signalling. However, RIP does not explain all EpCAM-derived protein fragments. To shed light on how proteolytic cleavage is involved in EpCAM signalling, we characterized the protein biochemically using antibodies binding to three different EpCAM domains. Using a newly generated anti-EpCAM antibody, we find that EpCAM can be cleaved at multiple positions within its ectodomain in addition to described peptides, revealing that EpCAM is processed via distinct proteolytic pathways. Here, we report on four new peptides, but also discuss the previously described cleavage products to provide a comprehensive picture of EpCAM cleavage at multiple positions. The complex regulation of EpCAM might not only result in the absence of full-length EpCAM, but the newly formed EpCAM-derived proteins may have their own signalling properties.     

EpCAM特异性适配体对胰腺癌细胞的靶向识别及促凋亡研究

目的:验证EpCAM分子特异性适配体对胰腺癌细胞的亲和性及对细胞凋亡的影响。方法:通过文献查询EpCAM分子特异性适配体,以流式细胞术验证适配体与胰腺癌PANC-1细胞的特异性亲和力;通过细胞免疫组化验证适配体与细胞结合的位点;通过流式细胞术检测适配体对细胞的凋亡影响。结果:选择文献报道的EpCAM分子特异性适配体EP166,在不破坏主要二级结构情况下做截断处理形成EP166s。通过流式细胞术验证发现EP166s与原适配体EP166均可以特异性识别胰腺癌PANC-1细胞,而与阴性对照的HEK293T细胞无特异性亲和力。细胞免疫荧光显示EP166s主要结合在细胞膜表面。凋亡检测结果发现EP166s在与PANC-1孵育12 h、24 h后均可促进细胞凋亡,且主要是细胞的早期凋亡,其所占百分比分别为12.2±0.20,27.13±0.36,而随机文库对照组的早期凋亡百分比分别为5.21±0.63,4.91±0.72;均值的配对T检验发现EP166s在孵育12 h和24 h后其早期凋亡所占百分数与随机文库组均有统计学差异,而且EP166s与细胞孵育12 h与24 h对凋亡的影响也有统计学差异,P≤0.01。结论:修饰后的适配体EP166s可以特异性识别胰腺癌PANC-1细胞,且结合位点位于细胞膜上;该适配体有促进PANC-1细胞凋亡的作用。     

Hypoxia modulates stem cell properties and induces EMT through N-glycosylation of EpCAM in breast cancer cells

Epithelial cell adhesion molecule (EpCAM), which is a transmembrane glycoprotein, is related to tumor progression. We demonstrated that EpCAM plays important roles in proliferation, apoptosis, and metastasis during breast cancer (BC) progression. But the role of N-glycosylation in EpCAM in tumor aggressiveness is not clear. Here, we evaluated the role of N-glycosylation of EpCAM in stemness and epithelial–mesenchymal transition (EMT) characteristics. EpCAM overexpression increases the expression of stemness markers (NANOG,SOX2, and OCT4) and EMT markers (N-cadherin and vimentin) under the condition of hypoxia in BC. Knockdown of EpCAM and mutation of N-glycosylation of EpCAM maintained in severe hypoxia lead to a significant reduction of stemness/EMT markers. In addition, we found that N-glycosylation of EpCAM is a crucial factor during this process. This demonstrates that EpCAM has a novel regulatory role in stemness/EMT dependence of hypoxia-inducible factor 1-alpha via regulating nuclear factor kappa B in BC cells. Hence, our study reveals EpCAM glycosylation modification as a new regulator of stemness/EMT under hypoxic in BC and points out EpCAM as a potential therapeutic target.     

FRET技术在受体信号转导研究中的应用

细胞信号传导是细胞生物学方面的重要内容之一,涉及生命过程的各个方面,包括生长、分化发育、增殖、凋亡、迁移等等,对维持细胞功能及机体生存至关重要。目前对细胞信号转导研究的技术手段多种多样,其中荧光共振能量转移技术（FRET）是研究细胞信号转导较为常用的一种技术,可以实现活细胞内蛋白质之间相互作用的实时检测。本文中我们以受体酪氨酸激酶为例,介绍FRET技术在受体介导细胞信号传导中的应用及进展情况。     

乳腺癌患者循环肿瘤细胞检测的研究进展

血行播散是乳腺癌转移的重要途径,检测腋窝淋巴结已经不能完全准确判断乳腺癌患者是否存在转移。肿瘤细胞进入外周血是肿瘤远处转移的前提,对乳腺癌患者循环肿瘤细胞的检测将有助于判断预后,指导治疗,监测治疗效果。简要综述了乳腺癌循环肿瘤细胞及其检测方法的研究进展。     

The cell-cell adhesion molecule EpCAM interacts directly with the tight junction protein claudin-7

We recently described that in the metastasizing rat pancreatic carcinoma line BSp73ASML the cell-cell adhesion molecule EpCAM, CD44 variant isoforms and the tetraspanins D6.1A and CD9 form a complex that is located in glycolipid-enriched membrane microdomains. This complex contains, in addition, an undefined 20 kDa protein. As such complex formation influenced cell-cell adhesion and apoptosis resistance, it became of interest to identify the 20 kDa polypeptide. This 20 kDa protein, which co-precipitated with EpCAM in BSp73ASML lysates, was identified as the tight junction protein claudin-7. Correspondingly, an association between EpCAM and claudin-7 was noted in rat and human tumors and in non-transformed tissues of the gastrointestinal tract. Co-localization of the two molecules was most pronounced at basolateral membranes, but was also observed in tight junctions. Evidence for direct protein-protein interactions between EpCAM and claudin-7 was obtained by co-immunoprecipitation after treatment of tumor cells with a membrane-permeable chemical cross-linker. The complex, which is located in glycolipid-enriched membrane microdomains, is not disrupted by partial cholesterol depletion, but claudin-7 phosphorylation is restricted to the localization in glycolipid-enriched membrane microdomains. This is the first report on an association between EpCAM and claudins in both non-transformed tissues and metastasizing tumor cell lines.     

前列腺癌的靶向治疗研究现状与展望

前列腺癌难以根治,研究雄激素非依赖型前列腺癌的靶向治疗具有实际的临床意义,涉及抗体靶向治疗、靶向抗前列腺癌药物研制、细胞生长信号转导通路抑制、微小RNA应用等多方面,而靶向清除肿瘤干细胞则是根治前列腺癌的有效策略。     

Mouse hepatoblasts at distinct developmental stages are characterized by expression of EpCAM and DLK1: Drastic change of EpCAM expression during liver development

Hepatoblasts are hepatic progenitor cells that expand and give rise to either hepatocyte or cholangiocytes during liver development. We previously reported that delta-like 1 homolog (DLK1) is expressed in the mouse liver primordium at embryonic day (E) 10.5 and that DLK1⁺ cells in E14.5 liver contain high proliferative and bipotential hepatoblasts. While the expression of epithelial cell adhesion molecule (EpCAM) in hepatic stem/progenitor cells has been reported, its expression profile at an early stage of liver development remains unknown. In this study, we show that EpCAM is expressed in mouse liver bud at E9.5 and that EpCAM⁺DLK1⁺ hepatoblasts form hepatic cords at the early stage of hepatogenesis. DLK1⁺ cells of E11.5 liver were fractionated into EpCAM⁺ and EpCAM⁻ cells; one forth of EpCAM⁺DLK1⁺ cells formed a colony in vitro whereas EpCAM⁻DLK1⁺ cells rarely did it. Moreover, EpCAM⁺DLK1⁺ cells contained cells capable of forming a large colony, indicating that EpCAM⁺DLK1⁺ cells in E11.5 liver contain early hepatoblasts with high proliferation potential. Interestingly, EpCAM expression in hepatoblasts was dramatically reduced along with liver development and the colony-forming capacities of both EpCAM⁺DLK1⁺ and EpCAM⁻DLK1⁺ cells were comparable in E14.5 liver. It strongly suggested that most of mouse hepatoblasts are losing EpCAM expression at this stage. Moreover, we provide evidence that EpCAM⁺DLK1⁺ cells in E11.5 liver contain extrahepatic bile duct cells as well as hepatoblasts, while EpCAM⁻DLK1⁺ cells contain mesothelial cell precursors. Thus, the expression of EpCAM and DLK1 suggests the developmental pathways of mouse liver progenitors.