Project description:Background & Aims: E-cadherin expression disruption is commonly observed in epithelial cancers and metastasis. Such event is also recognized as a crucial step in gastric cancer (GC) initiation and progression. As aberrant expression of microRNAs often perturb the normal expression and function of pivotal cancer-related genes, we characterized and dissected a pathway initiated by loss of microRNA-101 that causes E-cadherin dysfunction through upregulation of EZH2 expression in GC. Methods: Microarrays were used to profile the expression of microRNAs in human GC. Array-CGH revealed DNA copy number changes that were validated by genomic quantitative PCR and Snapshot. Expression levels of microRNAs, mRNA and protein were determined by quantitative-real time PCR and western-blot/co-immunofluorescence. CDH1 inactivating mechanisms were analyzed. Gain and loss of function experiments were done in KatoIII cells. E-cadherin functionality was assessed by immunofluorescence and flow cytometry. Results: MiR-101 expression was significantly decreased in tumors in comparison with normal gastric mucosas (P<.0001). In 65% of the analyzed GC cases, miR-101 downregulation was caused by deletions and/or microdeletions at miR-101-2 locus. EZH2 overexpression and consequent loss/aberrant E-cadherin expression was found in concomitance with miR-101 downregulation in 41% of the analyzed GC cases. This occurred preferentially in cases retaining allele(s) untargeted by classical CDH1 inactivating mechanisms. MiR-101 gain of function experiments or direct inhibition of EZH2, led to a strong depletion of endogenous EZH2 protein and consequent rescue of functional E-cadherin at the cell membrane, mimicking results obtained with clinical GC samples. Conclusions: Deletions and/or microdeletions at miR-101-2 locus underlying mature miR-101 downregulation and consequent EZH2 overexpression represented a novel cascade of genetic events leading to E-cadherin disruption, preferentially affecting the intestinal-type of GC. In the present study, 37 primary GCs and a pool of 10 normal gastric mucosas were used to acquire the expression of 703 known human mature miRNAs deposited in the Sanger miRBase Sequence Database, Release 10.0 (http://microrna.sanger.ac.uk), as well as 393 novel human miRNAs discovered through deep sequencing and validated by qRT-PCR and array profiling (NCodeM-bM-^DM-" Human miRNA microarray probe set V3 from Invitrogen). The 10 normal gastric mucosa RNA samples were pooled to obtain the normal gastric reference sample, which was labelled and hybridised four times to check arrays' reproducibility.

Project description:Diffuse-type gastric adenocarcinoma (DGAC) is lethal cancer that is often diagnosed late and resistant to therapeutics. Although hereditary DGAC is mainly characterized by mutations in the CDH1 gene that encodes E-cadherin, the impact of E-cadherin inactivation in DGAC tumorigenesis remains unclear. To address this, we established and characterized a CDH1 loss-associated DGAC model system with a human DGAC single-cell transcriptome. We genetically engineered murine gastric organoids (GOs; Cdh1 KO, KrasG12D, Trp53 KO [EKP]) that recapitulates human DGAC tumorigenesis. Cdh1 depletion is sufficient to 1. Single-cell transcriptomics of human DGAC datasets classified patients into three subtypes (DGAC1, 2, and 3). By transcriptional signature, EKP GOs belong to the DGAC1 subtype displaying CDH1 downregulation and epithelial-mesenchymal transition. Compared to DGAC2 and DGAC3, the DGAC1 subtype was characterized by T cell exhaustion, PILRA-CD99 enrichment, and potential sensitivity to PD1 inhibitors. Additionally, we identified the EZH2-mediated transcriptional circuit as a key regulon specifically activated in EKP and a therapeutic vulnerability. This study unravels the unexpected role of E-cadherin loss in cell lineage plasticity, transcriptional reprogramming, and immune evasion of DGAC and further stratifies DGAC patients by single-cell transcriptomics, providing novel insights into E-cadherin loss-associated DGAC tumorigenesis.

Project description:miR-101 is a tumor suppressive microRNA. Besides EZH2, a well known EZH2 target, miR-101 should have other targets, which might also contribute to its tumor suppressive function. Thus, we performed array hybridization to determine changes in gene expression upon miR-101 overexpression in U2OS cells.

Project description:Epidermal hyperplasia, a characteristic feature of psoriatic skin lesions, is epigenetically driven by Enhancer of Zeste homolog 2 (EZH2). EZH2 and EZH2-mediated trimethylation of histone H3 lysine 27 (H3K27me3) are both abnormally upregulated in psoriatic lesions. To identify microRNAs that could potentially target these epigenetic regulators we profiled miRNAs from psoriatic lesional skin in comparison with healthy skin. Analysis of the differentially expressed miRNAs revealed miR-101, as one of the most significant miRNA, consistently downregulated in psoriatic lesions compared to the healthy skin. A clear inverse correlation in the expression of miR-101 versus EZH2 was apparent in normal skin versus psoriatic lesional skin indicating that EZH2 is a potential target of miR-101, which was further confirmed by luciferase assay. Investigating the upstream effectors of the miR-101- EZH2 pathway in psoriasis, we identified the pro-inflammatory cytokine IL-17 as regulator of miR-101 expression. Here we propose a model, depicting a pathway triggered by IL-17 – mediated modulation of miR-101 expression, which in turn elicit sustained expression of EZH2, leading to enhanced keratinocyte proliferation and epidermal hyperplasia in psoriasis. Taken together, this indicates that miR-101 is a potential therapeutic target to alleviate the downstream effects of IL-17 mediated epidermal hyperplasia in psoriasis.

Project description:miR-101 is a tumor suppressive microRNA. Besides EZH2, a well known EZH2 target, miR-101 should have other targets, which might also contribute to its tumor suppressive function. Thus, we performed array hybridization to determine changes in gene expression upon miR-101 overexpression in U2OS cells. U2OS were transfected with synthetic miRNA negative control (NC) or miR-101 for 48hrs, and then harvested for RNA preparation. Three independent experiments were performed. One NC sample were repeated twice for the microarray.

Project description:To determine the phenotypic overlap between restoring miR-101 expression in bladder cancer cells and knocking down EZH2. Either control precursors, pre-miR-101, control siRNA, or EZH2 siRNA were transfected in triplicate into UM-UC-3 cells for 72 hours at a final concentration of 50 nM.

Project description:MicroRNA-101 (miR-101) is a tumour suppressor that regulates cancer proliferation and apoptotic signalling. Loss of miR-101 increases the expression of the Polycomb Repressive Complex 2 (PRC2) subunit enhancer of zeste homolog 2 (EZH2), resulting in alterations to the epigenome and enhanced tumorigenesis. MiR-101 has also been shown to modulate various aspects of cellular metabolism, however little is known about the mechanisms involved. To investigate the metabolic pathways that are regulated by miR-101, we performed transcriptome and functional analyses of osteosarcoma cells overexpressing miR-101. We found that miR-101 downregulates multiple mitochondrial processes, including oxidative phosphorylation, pyruvate metabolism, the citric acid cycle and phospholipid metabolism. We also found that miR-101 overexpression disrupts the transcription of mitochondrial DNA (mtDNA) via the downregulation of the mitochondrial transcription initiation complex proteins TFB2M and Mic60. These alterations in protein expression disrupt mitochondrial function, with significant decreases in both basal (54%) and maximal (67%) mitochondrial respiration rates. Native gel electrophoresis revealed that this diminished respiratory capacity was associated with reduced steady-state levels of mature succinate dehydrogenase (complex II), with a corresponding reduction of complex II enzymatic activity. Furthermore, miR-101 overexpression reduced the expression of the SDHB subunit, with a concomitant disruption of the assembly of the SDHC subunit into mature complex II. Overall, we describe a new role for miR-101 as a modulator of mitochondrial metabolism via its regulation of multiple mitochondrial processes, including mtDNA transcription and complex II biogenesis.

Project description:Background: E-cadherin is an adherens junction protein that forms homophilic intercellular contacts in epithelial cells while also interacting with the intracellular cytoskeletal networks. It has roles including establishment and maintenance of cell polarity, differentiation, migration and signalling in cell proliferation pathways. Its downregulation is commonly observed in epithelial tumours and is a hallmark of the epithelial to mesenchymal transition (EMT). Methods: To improve our understanding of how E-cadherin loss contributes to tumorigenicity, we investigated the impact of its elimination from the non-tumorigenic breast cell line MCF10A. We performed cell-based assays and whole genome RNAseq to characterize an isogenic MCF10A cell line that is devoid of CDH1 expression due to an engineered homozygous 4bp deletion in CDH1 exon 11. Results: The E-cadherin-deficient line, MCF10A CDH1-/- showed subtle morphological changes, weaker cell-substrate adhesion, delayed migration, but retained cell-cell contact, contact growth inhibition and anchorage-dependent growth. Within the cytoskeleton, the apical microtubule network in the CDH1-deficient cells lacked the radial pattern of organization present in the MCF10A cells and F-actin formed thicker, more numerous stress fibres in the basal part of the cell. Whole genome RNAseq identified compensatory changes in the genes involved in cell-cell adhesion while genes involved in cell-substrate adhesion, notably ITGA1, COL8A1, COL4A2 and COL12A1, were significantly downregulated. Key EMT markers including CDH2, FN1, VIM and VTN were not upregulated although increased expression of proteolytic matrix metalloprotease and kallikrein genes was observed. Conclusions: Overall, our results demonstrated that E-cadherin loss alone was insufficient to induce an EMT or enhance transforming potential in the non-tumorigenic MCF10A cells but was associated with broad transcriptional changes associated with tissue remodelling. Examination of the impact of E-cadherin (CDH1) loss in an isogenic pair of breast cell lines.

Project description:To determine the phenotypic overlap between restoring miR-101 expression in bladder cancer cells and knocking down EZH2.

Project description:Transcriptional analysis of genes in SKBr3 cells. Enhancer of zeste homolog 2 (EZH2) is a mammalian histone methyltransferase that contributes to the epigenetic silencing of target genes and regulates the survival and metastasis of cancer cells. EZH2 is overexpressed in aggressive solid tumors by mechanisms that remain unclear. Here we show that the expression and function of EZH2 in cancer cell lines are inhibited by microRNA-101 (miR-101).