Project description:miR-137 plays critical roles in the nervous system and tumor development. An increase in its expression is required for neuronal differentiation while its reduction is implicated in gliomagenesis. To evaluate the potential of miR-137 in glioblastoma therapy, we conducted genome-wide target mapping in glioblastoma cells by measuring levels of associations between PABP and mRNAs in cells transfected with miR-137 mimics vs. controls via RIPSeq. Impact on mRNA levels was also measured by RNASeq. By combining the results of both experimental approaches, 1468 genes were determined to be negatively impacted by miR-137; among them, 595 (40%) contain miR-137 predicted sites. The most relevant targets include oncogenic proteins and players in neurogenesis like c-KIT, YBX1, AKT2, CDC42, CDK6 and TGFβ2. Interestingly, we observed that several identified miR-137 targets are also predicted to be regulated by miR-124, miR-128 and miR-7, which are equally implicated in neuronal differentiation and gliomagenesis. We suggest that the concomitant increase of these four miRNAs in neuronal stem cells or their repression in tumor cells could produce a robust regulatory effect with major consequences to neuronal differentiation and tumorigenesis. Identification of genes affected by miR137 transfection via RIP-Seq and RNA-Seq in U251 and U343 cells

Project description:miR-137 plays critical roles in the nervous system and tumor development. An increase in its expression is required for neuronal differentiation while its reduction is implicated in gliomagenesis. To evaluate the potential of miR-137 in glioblastoma therapy, we conducted genome-wide target mapping in glioblastoma cells by measuring levels of associations between PABP and mRNAs in cells transfected with miR-137 mimics vs. controls via RIPSeq. Impact on mRNA levels was also measured by RNASeq. By combining the results of both experimental approaches, 1468 genes were determined to be negatively impacted by miR-137; among them, 595 (40%) contain miR-137 predicted sites. The most relevant targets include oncogenic proteins and players in neurogenesis like c-KIT, YBX1, AKT2, CDC42, CDK6 and TGFβ2. Interestingly, we observed that several identified miR-137 targets are also predicted to be regulated by miR-124, miR-128 and miR-7, which are equally implicated in neuronal differentiation and gliomagenesis. We suggest that the concomitant increase of these four miRNAs in neuronal stem cells or their repression in tumor cells could produce a robust regulatory effect with major consequences to neuronal differentiation and tumorigenesis.

Project description:Genetic analyses have linked microRNA-137 (MIR137) to neuropsychiatric disorders, including schizophrenia and autism spectrum disorder. miR-137 plays important roles in neurogenesis and neuronal maturation, but the impact of miR-137 loss-of-function in vivo remains unclear. Here we show the complete loss of miR-137 in the mouse germline (gKO) or nervous system (cKO) leads to postnatal lethality, while heterozygous gKO and cKO mice remain viable. Partial loss of miR-137 in heterozygous cKO mice results in dysregulated synaptic plasticity, repetitive behavior, and impaired learning and social behavior. Transcriptomic and proteomic analyses revealed that the miR-137 mRNA target, phosphodiesterase 10a (Pde10a), is elevated in heterozygous knockout mice. Treatment with the Pde10a inhibitor papaverine or knockdown of Pde10a ameliorates the deficits observed in the heterozygous cKO mice. Collectively, our results suggest that MIR137 plays essential roles in postnatal neurodevelopment and that dysregulation of miR-137 potentially contributes to neuropsychiatric disorders in humans.

Project description:Recent genetic evidence has revealed microRNA-137 (miR-137) as a risk gene in schizophrenia and autism spectrum disorder (ASD), and the following cellular studies have demonstrated the importance of miR-137 in regulating neurogenesis. We have generated miR-137 knockout mice which display behaviors that resemble some symptoms of these two diseases. To investigate the underlying molecular mechanism, we performed comprehensive analyses of the entire RNA and protein molecules of the miR-137 mouse brains. The dataset uploaded here is the raw data of the mass spectrometry-based whole proteome analysis of the six miR-137 mouse brains: wild-type, heterozygous (miR-137+/–) and homozygous (miR-137–/–) from two different litters. The tandem mass tag (TMT) methodology was employed in this proteomics analysis for the quantitation. The sample channels are: 128C (miR-137+/+, litter 1), 129N (miR-137+/–, litter 1), 129C (miR-137–/–, litter 1), 130N (miR-137+/+, litter 2), 130C (miR-137+/–, litter 2), and 131N (miR-137–/–, litter 2).

Project description:A hallmark of cortical evolution is the high dynamic subventricular zone (SVZ) expansion, where basal progenitors (BPs) amplify and neuronal transcriptional programs unfold. How non-coding molecular factors such as microRNAs influence these developmental trajectories and regulate the acquisition of cortical type identities is largely unknown. Here we demonstrate that miR-137 and miR-122 regulate the positioning and identity features of superficial layer cortical neurons by acting at distinct steps of their developmental trajectories. MiR-137 sustains basal progenitor amplification by reverting their neurogenic commitment and inducing high proliferative state upregulating Cd63 and inhibiting Myt1l. Cd63 is an extra-cellular matrix (ECM) receptor which interacts with b3- and 1-integrin pathways to promote proliferation, while Myt1l is a transcription factor that promotes and sustains neuronal fate. The BPs amplification by miR-137 is converted in the promotion of intracortical projecting neuron (ICPN) identity and L2/3 expansion. As opposed to miR-137, miR-122 acts postmitotically, affecting the bioelectrical properties, the calcium and cytoskeleton dynamics of newborn neurons as well as their transcriptional program, leading to a persistent molecular immaturity across time. Overall, these findings reveal that miR-137 and miR-122 are key regulators of the developmental trajectory of cortical neurons across evolution.

Project description:MicroRNAs are short non-coding RNA molecules playing regulatory roles in animals and plants by repressing translation or cleaving RNA transcripts. The specific modulation of several microRNAs has been recently associated to some forms of human cancer, suggesting that these short molecules can represent a new class of genes involved in oncogenesis. In our study, we examined by microarray the global expression levels of 245 microRNAs in glioblastoma multiforme (GBM), the most frequent and malignant of primary brain tumors. The analysis of both glioblastoma tissues and glioblastoma cell lines allowed us to identify a group of microRNAs whose expression is significantly altered in this tumor. The most interesting results came from miR-221, strongly upregulated in glioblastoma and a set of brain-enriched miRNAs, miR-128, miR-181a, miR-181b, miR-181c, which are down-regulated in glioblastoma.

Project description:MicroRNAs (miRNAs) are small (21-25 nucleotide in length) non-coding RNA molecules that negatively regulate protein expression. They are linked to cancer development and maintenance. In this work, studying gene expression profiles of 340 mammalian miRNAs with DNA microarrays, we selected 10 miRNAs gene features able to distinguish primary from secondary glioblastoma type; furthermore we verified that miR-21 and miR-155 up-regulatation seems to characterize the glioblastoma tumour state since it was found up-regulated in all samples analyzed compared to adult brain noneoplastic tissue. Since miR-21 function in glioblastoma cells was addressed previously we concentrated our efforts on miR-155 function. We found that miR-155 levels were markedly elevated both in primary and secondary glioblastomas tumours, in glioblastoma cell cultures and in 4 glioblastoma cell lines (U87, A172, LN229, and LN308) compared with adult brain tissue, CHP212-neuroblastoma cell lines and DAOY-1-medulloblastoma cell line. Since one of the miR-155 target was gamma-aminobutyric acid (GABA) A receptor (GABRA1) we verified if there was a relation between miR-155 up-regulation and GABRA1 expression. We demonstrated that, in cultured glioblastoma cells, knockdown of miR-155, which lower miR-155 expression to normal level, restore the normal expression of the gamma-aminobutyric acid (GABA) A receptor (GABRA1), making glioblastoma cells responsive to GABA cell cycle inhibiting signals. Our data suggest that aberrantly over-expressed miR-155 contribute to the malignant phenotype of the glioblastoma cells, promoting their unlimited growth. Keywords: miRNA expression profile We studied the expression profiles of 340 miRNAs in 97 glioblastoma tissues, of which 66 were primary glioblastomas and 27 were secondary glioblastomas. We have 66 replicates of primary glioblastoma and 27 replicates of secondary glioblastoma, each hybridized with the respective adult non-neoplastic brain tissue as a control.

Project description:Purpose: The goals of this study is to uncover the difference of transcriptomes that are essential for HSCs malignant transformation driven by miR-31-5p inhibition. Methods: GFP+-HSCs sorted from bone marrow mRNA profiles of mice receiving HSCs subjected to control RNA or miR-31-5p inhibitor treatment were generated by deep sequencing, using Illumina NovaSeq 6000 sequencer for 318 cycles.Reads that passed the Illumina quality filters were kept for the subsequent analyses. Adapters were trimmed from the reads, and reads shorter than 17 nt were discarded. The reads were mapped to the Mouse mRNA reference database using FANSe3 algorithm on Chi-Cloud NGS Analysis Platform (Chi-Biotech Co. Ltd., Shenzhen, China). Results: We use edgeR to analysis with a |log2 (FoldChange)| > 1 and p value <0.01. Hierarchical clustering of differentially expressed genes uncovered several as yet uncharacterized genes that may contribute to promote HSCs malignant driven by miR-31-5p inhibition. Conclusions: Our study represents the first detailed analysis of transcriptomes that promote T-cell malignant transformation driven by HTVL-1 oncogene Tax.

Project description:We report an upregulation of miR-16 in Paget's disease of bone which is to target the SQSTM1. When miR-16 is lost in Paget's disease, there is malignant transformation.

Project description:To clarify the effect of miRNAs, we carried out a gene expression microarray analysis of SW780 cells transfected with a miR-137 precursor or a negative control. We found that 1,326 probe sets (1,016 unique genes) were downregulated (>2-fold) by ectopic miR-137 expression, including the previously reported miR-137 target genes CDK6, CDC42 and AURKA. Moreover, Gene Ontology analysis revealed that genes related to the cell cycle were significantly enriched among the affected genes. SW780 cells were transfected with a Pre-miR-137 miRNA Precursor Molecule (Ambion) or Pre-miR miRNA Molecules Negative Control #1 (Ambion). Forty-eight hours after transfection, total RNA extraction was carried out, and gene expression signatures were analyzed.