Project description:MicroRNAs are small non-coding RNA species, some of which are playing important roles in cell differentiation. However, the level of participations of microRNAs in epithelial cell differentiation is largely unknown. Here, we found that expression levels of four microRNAs (miR-210, miR-338-3p, miR-33a and miR-451) were significantly increased in differentiated stage of T84 cells, compared with undifferentiated stage. Additionally, we demonstrate that miR-338-3p and miR-451 contribute to the formation of epithelial basolateral polarity by facilitating translocalization of beta1 integrin to the basolateral membrane. However, candidate target mRNAs of miR-338-3p and miR-451 and the mechanism behind observed phenomena is uncertain. Then, we performed comprehensive gene expression analysis to identify candidate target mRNAs and understand their mechanisms. T84 cells were seeded in transwell chambers and were transfected with microRNAs. Total RNA was extracted by the acid guanidinium thiocyanate-phenol-chloroform method, and was labeled and prepared for hybridization to GeneChip Human Genome U133 Plus 2.0 arrays (Affymetrix) according to the manufacture’s instructions (standard protocol).

Project description:In this study, we comparatively analyzed the members of the miR-449 family (miR-449a, miR-449b, and miR-449c) with regards to their target genes and functional effects in hepatocellular carcinoma (HCC). Microarray analysis after transient transfection of miR-449a, miR-449b, and/or miR-449c in the HCC cell line HLE identified putative target genes of miR-449a, miR-449b, and miR-449c. For transient overexpression of miRNAs, the HCC cell line HLE was transfected with 50 nM Allstars Negative Control or miScript miRNA mimics. MiRNA mimics for miR-449a, miR-449b, and miR-449c were either single transfected or cotransfected in equimolar amounts (16.7 nM each). Global mRNA expression profiling was performed utilizing pooled RNA of three biological replicates per microarray and two microarrays per condition.

Project description:Persistent colonization of the gastric mucosa by Helicobacter pylori (Hp) elicits chronic inflammation and aberrant epithelial cell proliferation, which increases the risk of gastric cancer. We examined the ability of microRNAs to modulate gastric cell proliferation in response to persistent Hp infection and found that epigenetic silencing of miR-210 plays a key role in gastric disease progression. Importantly, DNA methylation of the miR-210 gene was increased in Hp-positive human gastric biopsies as compared to Hp-negative controls. Moreover silencing of miR-210 in gastric epithelial cells promoted proliferation. We identified STMN1 and DIMT1 as miR-210 target genes and demonstrated that inhibition of miR-210 expression augmented cell proliferation by activating STMN1 and DIMT1. Together, our results highlight inflammation-induced epigenetic silencing of miR-210 as a mechanism of induction of chronic gastric diseases, including cancer, during Hp infection. To identify miR-210 targets in gastric cells, whole transcriptome analysis of AGS and MKN45 cells transfected with pre-miR-210 was conducted using Affymetrix GeneChip Human Genome U133 Plus 2.0 Array.

Project description:Persistent colonization of the gastric mucosa by Helicobacter pylori (Hp) elicits chronic inflammation and aberrant epithelial cell proliferation, which increases the risk of gastric cancer. We examined the ability of microRNAs to modulate gastric cell proliferation in response to persistent Hp infection and found that epigenetic silencing of miR-210 plays a key role in gastric disease progression. Importantly, DNA methylation of the miR-210 gene was increased in Hp-positive human gastric biopsies as compared to Hp-negative controls. Moreover silencing of miR-210 in gastric epithelial cells promoted proliferation. We identified STMN1 and DIMT1 as miR-210 target genes and demonstrated that inhibition of miR-210 expression augmented cell proliferation by activating STMN1 and DIMT1. Together, our results highlight inflammation-induced epigenetic silencing of miR-210 as a mechanism of induction of chronic gastric diseases, including cancer, during Hp infection.

Project description:MicroRNAs are small, non-coding RNAs that regulate gene expression post-transcriptionally. Here, we show that miR-210 is induced by Oct-2, a key transcriptional mediator of B-cell activation. Germline deletion of miR-210 results in the development of autoantibodies from 5 months of age. Overexpression of miR-210 in vivo resulted in cell autonomous expansion of the B1 lineage and impaired fitness of B2 cells. Mice over-expressing miR-210 exhibited impaired class-switched antibody responses, a finding confirmed in wild-type B-cells transfected with a miR-210 mimic. In vitro studies demonstrated a defect in cellular proliferation and cell-cycle entry, which was consistent with the transcriptomic analysis demonstrating down-regulation of genes involved in cellular proliferation and B cell activation. These findings indicate that Oct-2 induction of miR-210 provides a novel inhibitory mechanism for the control of B cells and autoantibody production.

Project description:Recent studies have identified miR-210 among a set of hypoxia-regulated miRNAs, and shown the central regulatory role played by HIF to control transcription of this miRNA. Contradictory data exist concerning the regulation and roles of miR-210 during cancer progression. miR-210 appears at the same time over-expressed in some solid tumors (breast, pancreas, head and neck carcinomas, gliomas) while often deleted in ovarian carcinoma. It has been shown that depending on the tissue type or cellular model, miR-210 was indeed able to either promote entry into the cell cycle and to inhibit apoptosis or rather repress tumor initiation. We show here deregulation of several miRNAs in human lung cancer biopsies, including an over-expression of miR-210 which appears specific of late-stages of the tumor (>stage 2). MiR-210 function was then analyzed in the lung adenocarcinoma cell line A549. We found that miR-210 induced a delayed inhibition of proliferation associated with an induction of cell death. We also observed that mir-210 induces a loss of mitochondrial membrane potential and the apparition of an aberrant mitochondrial phenotype. mRNA expression profiling of cells overexpressing mir-210 revealed a specific signature characterized by an enrichment in mir-210 predicted targets among the downregulated transcripts (57 out of 243, p<10-12). Functional annotation of this set of mir-210-regulated transcripts, which includes several subunits of Electron Transport Chain (ETC) complex I and complex II revealed enrichment for terms such as 'cell death' and 'mitochondrial dysfunction'. Two of these ETC subunits, predicted to be targets of mir-210 by several bioinformatics prediction tools, were experimentally confirmed after cloning of their respective 3'UTR in a luciferase reporter vector. Finally, we provide experimental evidence indicating that these mitochondrial alterations could modulate HIF via a positive regulatory loop. Overall, our data strongly suggest that mir-210 could mediate two apparently opposite functions: i) apoptosis through targeting of specific mitochondrial components ii) a modulation of HIF through a positive regulatory loop. We propose that this dual behavior can explain the contradictory data regarding the impact of miR-210 during cancer progression. This SuperSeries is composed of the SubSeries listed below.

Project description:The resistance of hypoxic cells to radiotherapy and chemotherapy is a major problem in the treatment of cancer. Recently, an additional level of Hypoxia Inducible Factor (HIF) dependent transcriptional regulation has emerged involving modulation of a specific set of miRNAs including miR-210. We have recently shown that HIF-1 induction of miR-210 also stabilizes HIF-1 through a positive regulatory loop. We therefore hypothesized that by stabilizing HIF-1 in normoxia, miR-210 may protect cancer cells from radiation. We developed Non-Small Cell Lung Cancer (NSCLC)-derived cell lines (A549 and H1975) stably expressing miR-210 (pmiR-210) or a control miRNA (pmiR-Ctl). MiR-210 expressing cells showed a significant stabilization of HIF-1 associated with mitochondrial defects and a glycolytic phenotype. The cells were subjected to radiation levels ranging from 0 to 10Gy in normoxia and hypoxia. Cells expressing miR-210 in normoxia had the same level of resistance than control cells in hypoxia. pmiR-210 cells under hypoxia showed a low mortality rate due to a decrease in apoptosis and an ability to grow even at 10Gy. We have established that radioresistance was independent of p53 and cell cycle status. In addition, we show here that genomic double strand breaks (DSB) foci disappeared faster in pmiR-210 than in pmiR-Ctl cells, suggesting that miR-210 expression promotes a more efficient DSB repair. Finally, HIF-1 invalidation in pmiR-210 cells (pmiR-210/HIF-1-) abolished radioresistance of cells showing that this mechanism was dependent upon HIF-1. In conclusion, miR-210 appears to be a major component in the radioresistance of hypoxic cancer cells. Given the high stability of most miRNAs, this advantage could even be used by tumor cells in conditions where hypoxia may not be present anymore and strongly suggests that strategies targeting miR-210 would enhance tumor radiosensitization.

Project description:The resistance of hypoxic cells to radiotherapy and chemotherapy is a major problem in the treatment of cancer. Recently, an additional level of Hypoxia Inducible Factor (HIF) dependent transcriptional regulation has emerged involving modulation of a specific set of miRNAs including miR-210. We have recently shown that HIF-1 induction of miR-210 also stabilizes HIF-1 through a positive regulatory loop. We therefore hypothesized that by stabilizing HIF-1 in normoxia, miR-210 may protect cancer cells from radiation. We developed Non-Small Cell Lung Cancer (NSCLC)-derived cell lines (A549 and H1975) stably expressing miR-210 (pmiR-210) or a control miRNA (pmiR-Ctl). MiR-210 expressing cells showed a significant stabilization of HIF-1 associated with mitochondrial defects and a glycolytic phenotype. The cells were subjected to radiation levels ranging from 0 to 10Gy in normoxia and hypoxia. Cells expressing miR-210 in normoxia had the same level of resistance than control cells in hypoxia. pmiR-210 cells under hypoxia showed a low mortality rate due to a decrease in apoptosis and an ability to grow even at 10Gy. We have established that radioresistance was independent of p53 and cell cycle status. In addition, we show here that genomic double strand breaks (DSB) foci disappeared faster in pmiR-210 than in pmiR-Ctl cells, suggesting that miR-210 expression promotes a more efficient DSB repair. Finally, HIF-1 invalidation in pmiR-210 cells (pmiR-210/HIF-1-) abolished radioresistance of cells showing that this mechanism was dependent upon HIF-1. In conclusion, miR-210 appears to be a major component in the radioresistance of hypoxic cancer cells. Given the high stability of most miRNAs, this advantage could even be used by tumor cells in conditions where hypoxia may not be present anymore and strongly suggests that strategies targeting miR-210 would enhance tumor radiosensitization. To identify the set of transcripts targeted by miR-210, we overexpressed has-miR-210 or a control miRNA (ce-miR-67) in human lung adenocarcinoma A549 cells by transduction using lentivirus. The resulting pmiR-67 and pmiR-210 that stably overexpress miR-210 were selected by puromycin. RNA samples were harvested at 2 different times following cell plating (24 hours or 48 hours). Experiments were performed in dye-swap.

Project description:As miR-210 expression is correlated to poor prognosis both in estrogen-positive and in estrogen-negative breast cancer (BC) patients, we aimed to investigate the biological processes regulated by miR-210 and which may elucidate its function in the aggressive phenotype of high grade breast cancer. We performed in silico functional analyses of the genes deregulated upon miR-210 overexpression in MCF7 BC cell line and upon miR-210 repression in MDA-MB-231 BC cell line using lentiviral transduction. Gene expression profiling analysis of these cells revealed the deregulation of genes involved in several biological pathways including cell adhesion, extracellular structure organization, epithelial cell proliferation, cell division, cell cycle and immune response. MCF-7 cells overexpressing miR-210 (or control) and MDA-MB-231 cells in which miR-210 (or control) is repressed were used for RNA extraction and hybridization on Affymetrix microarrays.

Project description:MicroRNAs (miRNAs) are small non-protein-coding RNAs that are incorporated into the RNA-induced silencing complex (RISC) and inhibit gene expression by regulating the stability and/or the translational efficiency of target mRNAs. Previously, we demonstrated that miR-210 is a key player of endothelial cell (EC) response to hypoxia, modulating EC survival, migration and ability to form capillary like-structures. Moreover, the receptor tyrosine kinase ligand Ephrin-A3 was identified as one functionally relevant target. Since each miRNA regulates hundreds of mRNAs, different approaches were combined to identify new miR-210 targets: a Using target prediction software, 32 new miR-210 potential targets were identified. b The proteomic profiling of miR-210 over-expressing ECs identified 11 proteins that were specifically inhibited by miR-210, either directly or indirectly. c Affymetrix based gene expression profiles identified 51 genes that were both down-modulated by miR-210 over-expression and de-repressed when miR-210 was blocked. Surprisingly, only few genes identified either by proteomics or transcriptomics were recognized as miR-210 targets by target prediction algorithms. However, a low-stringency pairing research revealed enrichment for miR-210 putative binding sites, raising the possibility that these genes were targeted via non-canonical recognition sequences. To clarify this issue, miR-210-loaded RISC was purified by immuno-precipitation along with its mRNA targets. The presence of Ephrin-A3 mRNA in the complex validated this approach. We found that 32 potential targets were indeed enriched in miR-210-loaded RISC, and thus can be considered as genuine miR-210 targets. In keeping with this conclusion, we were able to further validate a sub-set of them by 3’UTR-reporter assays. Gene ontology analysis of the targets confirmed the known miR-210 activity in differentiation and cell cycle regulation, highlighting new functions such as involvement in RNA processing, DNA binding, development, membrane trafficking and amino acid catabolism. In conclusion, we validated a multidisciplinary approach for miRNAs target identification and indicated novel molecular mechanisms underpinning miR-210 role in EC response to hypoxia.