EMT参与肿瘤侵袭转移的研究进展

在癌症类型中,上皮癌占绝大多数。从良性腺瘤过渡到恶性癌和转移期间,上皮肿瘤细胞获得去分化、迁移和入侵行为,同时上皮-间质转化（epithelial-mesenchymal transition EMT）伴随着显著的细胞形态学变化、细胞与细胞间及细胞与基质之间的粘附性丢失及重塑、并获得迁徙和侵袭能力。正如完全分化的上皮细胞转换成低分化、迁移和侵入性间质细胞,其涉及到一个高度的细胞可塑性、大量不同的基因和表观遗传学改变,因此EMT本身是一个多阶段的过程。该综述的目的是系统地总结EMT分子机制及EMT与肿瘤关系的最新进展。     

EMT参与肿瘤侵袭转移的研究进展

在癌症类型中,上皮癌占绝大多数。从良性腺瘤过渡到恶性癌和转移期间,上皮肿瘤细胞获得去分化、迁移和入侵行为,同时上皮-间质转化(epithelial-mesenchymal transition EMT)伴随着显著的细胞形态学变化、细胞与细胞间及细胞与基质之间的粘附性丢失及重塑、并获得迁徙和侵袭能力。正如完全分化的上皮细胞转换成低分化、迁移和侵入性间质细胞,其涉及到一个高度的细胞可塑性、大量不同的基因和表观遗传学改变,因此EMT本身是一个多阶段的过程。该综述的目的是系统地总结EMT分子机制及EMT与肿瘤关系的最新进展。     

EGFR Signal-Network Reconstruction Demonstrates Metabolic Crosstalk in EMT

Epithelial to mesenchymal transition (EMT) is an important event during development and cancer metastasis. There is limited understanding of the metabolic alterations that give rise to and take place during EMT. Dysregulation of signalling pathways that impact metabolism, including epidermal growth factor receptor (EGFR), are however a hallmark of EMT and metastasis. In this study, we report the investigation into EGFR signalling and metabolic crosstalk of EMT through constraint-based modelling and analysis of the breast epithelial EMT cell model D492 and its mesenchymal counterpart D492M. We built an EGFR signalling network for EMT based on stoichiometric coefficients and constrained the network with gene expression data to build epithelial (EGFR_E) and mesenchymal (EGFR_M) networks. Metabolic alterations arising from differential expression of EGFR genes was derived from a literature review of AKT regulated metabolic genes. Signaling flux differences between EGFR_E and EGFR_M models subsequently allowed metabolism in D492 and D492M cells to be assessed. Higher flux within AKT pathway in the D492 cells compared to D492M suggested higher glycolytic activity in D492 that we confirmed experimentally through measurements of glucose uptake and lactate secretion rates. The signaling genes from the AKT, RAS/MAPK and CaM pathways were predicted to revert D492M to D492 phenotype. Follow-up analysis of EGFR signaling metabolic crosstalk in three additional breast epithelial cell lines highlighted variability in in vitro cell models of EMT. This study shows that the metabolic phenotype may be predicted by in silico analyses of gene expression data of EGFR signaling genes, but this phenomenon is cell-specific and does not follow a simple trend.     

Epithelial-mesenchymal transition and the stem cell phenotype

Epithelial-mesenchymal transition (EMT) is a developmental process in which epithelial cells acquire the motile, migratory properties of mesenchymal cells. In a recent issue of Cell, Mani et al. (2008) show that induction of EMT stimulates cultured breast cells to adopt characteristics of stem cells.     

Sustained co-cultivation with human placenta-derived MSCs enhances ALK5/Smad3 signaling in human breast epithelial cells,leading to EMT and differentiation

The interaction between mammary epithelial cells and their surrounding microenvironment are important in the development of the mammary gland. Thus, mesenchymal stem cells (MSCs), which retain pluripotency for various mesenchymal lineages, may provide a permissive environment for the morphologic alteration and differentiation of mammary epithelial cells. To this end, we investigated whether the interactions between mammary epithelial cells and human placenta-derived MSCs (hPMSC) affect the morphology, proliferation, and differentiation of epithelial cells in a co-culture system. We show that after co-culture with hPMSCs, human mammary epithelial cell lines (MCF-10F and HEMC) underwent significant morphologic alterations and a dramatic increase in ductal–alveolar branching, which was accompanied by a decrease or loss of the epithelial marker E-cadherin and a gain of the mesenchymal markers, α-SMA and vimentin. MCF-10F and HEMC proliferation was also inhibited in the presence of hPMSCs, and this retardation in growth was due to cell cycle arrest. Furthermore, in MCF-10F and HMEC cells, hPMSCs induced the production of lipid droplets, milk fat globule protein, and milk protein lactoferrin, which are markers of functional mammary differentiation. We also noticed an elevation in ALK5 and phosphorylated Smad3 protein levels upon hPMSC co-culture. Strikingly, the changes in morphology, proliferation, and differentiation were reversed by treatment with ALK5 or Smad3 knockdown in MCF-10F/hPMSC co-cultures. Collectively, our findings suggest that co-cultivation with hPMSCs leads to epithelial to mesenchymal transition (EMT) and differentiation of human breast epithelial cells through the ALK5/Smad3 signaling pathway.     

An in vitro model that recapitulates the epithelial to mesenchymal transition (EMT) in human breast cancer

The epithelial to mesenchymal transition (EMT) is a developmental program in which epithelial cells down-regulate their cell-cell junctions, acquire spindle cell morphology and exhibit cellular motility. In human breast cancer, invasion into surrounding tissue is the first step in metastatic progression. Here, we devised an in vitro model using selected cell lines, which recapitulates many features of EMT as observed in human breast cancer. By comparing the gene expression profiles of claudin-low breast cancers with the experimental model, we identified a 9-gene signature characteristic of EMT. This signature was found to distinguish a series of breast cancer cell lines that have demonstrable, classical EMT hallmarks, including loss of E-cadherin protein and acquisition of N-cadherin and vimentin expression. We subsequently developed a three-dimensional model to recapitulate the process of EMT with these cell lines. The cells maintain epithelial morphology when encapsulated in a reconstituted basement membrane, but undergo spontaneous EMT and invade into surrounding collagen in the absence of exogenous cues. Collectively, this model of EMT in vitro reveals the behaviour of breast cancer cells beyond the basement membrane breach and recapitulates the in vivo context for further investigation into EMT and drugs that may interfere with it.     

Interplay between p53 and non-coding RNAs in the regulation of EMT in breast cancer

The epithelial–mesenchymal transition (EMT) plays a pivotal role in the differentiation of vertebrates and is critically important in tumorigenesis. Using this evolutionarily conserved mechanism, cancer cells become drug-resistant and acquire the ability to escape the cytotoxic effect of anti-cancer drugs. In addition, these cells gain invasive features and increased mobility thereby promoting metastases. In this respect, the process of EMT is critical for dissemination of solid tumors including breast cancer. It has been shown that miRNAs are instrumental for the regulation of EMT, where they play both positive and negative roles often as a part of a feed-back loop. Recent studies have highlighted a novel association of p53 and EMT where the mutation status of p53 is critically important for the outcome of this process. Interestingly, p53 has been shown to mediate its effects via the miRNA-dependent mechanism that targets master-regulators of EMT, such as Zeb1/2, Snail, Slug, and Twist1. This regulation often involves interactions of miRNAs with lncRNAs. In this review, we present a detailed overview of miRNA/lncRNA-dependent mechanisms that control interplay between p53 and master-regulators of EMT and their importance for breast cancer.Subject terms: Breast cancer, Long non-coding RNAs, miRNAs