Project description:This SuperSeries is composed of the following subset Series: GSE29043: MicroRNAs and their isomiRs function cooperatively to target common biological pathways (Illumina expression beadchip) GSE29100: MicroRNAs and their isomiRs function cooperatively to target common biological pathways (Agilent miRNA array) Refer to individual Series This represents the miRNA placenta samples and mRNA + miRNA pulldown only The miRNA-Seq data have been submitted to the short read archive under SRA number SRP006043: http://www.ncbi.nlm.nih.gov/sra?term= SRP006043
Project description:Variants of microRNAs, (isomiRs) are commonly reported in deep-sequencing studies; however the functional significance of these variants remains controversial. To assess their biological relevance, we have performed ultra-deep miRNA-seq on ten adult human tissues, and created an analysis pipeline (miRNA-MATE) to align, annotate, and analyze miRNAs and their isomiRs. We find that isomiRs share sequence and expression characteristics with canonical miRNAs, and are generally strongly correlated with canonical miRNA expression. We isolated polyribosome-associated mRNA, and captured the mRNA-bound miRNAs, and found that isomiRs and canonical miRNAs are equally associated with translational machinery. Finally, we transfected cells with biotinylated RNA duplexes encoding isomiRs or their canonical counterparts and directly assayed their mRNA targets. These studies showed substantial overlap in functional mRNA networks suppressed by both canonical miRNAs and their isomiRs. Together, these results find isomiRs to be biologically relevant and functionally synergistic partners of canonical miRNAs that act coordinately to target pathways of functionally related genes. This work exposes the complexity of the miRNA-transcriptome, and helps explain a major miRNA paradox: how specific regulation of biological processes can occur with predominantly non-specific miRNA-mRNA interactions. HEK293T cells were transfected with biotinylated miRNAs (either mir-10a-iso, mir-10a, mir-10b-iso or mir-10b) or a mock control. The miRNAs and target mRNA were pulled down with streptavidin. The pulled down RNA was hybridised to Illumina microarrays. The miRNA-Seq data have been submitted to the short read archive under SRA number SRP006043: http://www.ncbi.nlm.nih.gov/sra?term= SRP006043
Project description:Variants of microRNAs, (isomiRs) are commonly reported in deep-sequencing studies; however the functional significance of these variants remains controversial. To assess their biological relevance, we have performed ultra-deep miRNA-seq on ten adult human tissues, and created an analysis pipeline (miRNA-MATE) to align, annotate, and analyze miRNAs and their isomiRs. We find that isomiRs share sequence and expression characteristics with canonical miRNAs, and are generally strongly correlated with canonical miRNA expression. We isolated polyribosome-associated mRNA, and captured the mRNA-bound miRNAs, and found that isomiRs and canonical miRNAs are equally associated with translational machinery. Finally, we transfected cells with biotinylated RNA duplexes encoding isomiRs or their canonical counterparts and directly assayed their mRNA targets. These studies showed substantial overlap in functional mRNA networks suppressed by both canonical miRNAs and their isomiRs. Together, these results find isomiRs to be biologically relevant and functionally synergistic partners of canonical miRNAs that act coordinately to target pathways of functionally related genes. This work exposes the complexity of the miRNA-transcriptome, and helps explain a major miRNA paradox: how specific regulation of biological processes can occur with predominantly non-specific miRNA-mRNA interactions.
Project description:This data set is part of a larger study: Variants of microRNAs, (isomiRs) are commonly reported in deep-sequencing studies; however the functional significance of these variants remains controversial. To assess their biological relevance, we have performed ultra-deep miRNA-seq on ten adult human tissues, and created an analysis pipeline (miRNA-MATE) to align, annotate, and analyze miRNAs and their isomiRs. We find that isomiRs share sequence and expression characteristics with canonical miRNAs, and are generally strongly correlated with canonical miRNA expression. We isolated polyribosome-associated mRNA, and captured the mRNA-bound miRNAs, and found that isomiRs and canonical miRNAs are equally associated with translational machinery. Finally, we transfected cells with biotinylated RNA duplexes encoding isomiRs or their canonical counterparts and directly assayed their mRNA targets. These studies showed substantial overlap in functional mRNA networks suppressed by both canonical miRNAs and their isomiRs. Together, these results find isomiRs to be biologically relevant and functionally synergistic partners of canonical miRNAs that act coordinately to target pathways of functionally related genes. This work exposes the complexity of the miRNA-transcriptome, and helps explain a major miRNA paradox: how specific regulation of biological processes can occur with predominantly non-specific miRNA-mRNA interactions.
Project description:The microRNA (miRNA) processing is a critical step for production of mature miRNAs. Its dysregulation leads to the increase of miRNA isoforms with heterogenous 5’ ends (isomiRs), recognizing distinct target sites with a shifted seed sequence. Although some miRNA genes display productive expression of their 5’-isomiRs in cancers, how the production is controlled and how they impact on tumor progression are unexplored yet. In this study, we identified tumor-specific production of isomiRs and investigated biological function of isomiRs in liver cancer.
Project description:This data set is part of a larger study: Variants of microRNAs, (isomiRs) are commonly reported in deep-sequencing studies; however the functional significance of these variants remains controversial. To assess their biological relevance, we have performed ultra-deep miRNA-seq on ten adult human tissues, and created an analysis pipeline (miRNA-MATE) to align, annotate, and analyze miRNAs and their isomiRs. We find that isomiRs share sequence and expression characteristics with canonical miRNAs, and are generally strongly correlated with canonical miRNA expression. We isolated polyribosome-associated mRNA, and captured the mRNA-bound miRNAs, and found that isomiRs and canonical miRNAs are equally associated with translational machinery. Finally, we transfected cells with biotinylated RNA duplexes encoding isomiRs or their canonical counterparts and directly assayed their mRNA targets. These studies showed substantial overlap in functional mRNA networks suppressed by both canonical miRNAs and their isomiRs. Together, these results find isomiRs to be biologically relevant and functionally synergistic partners of canonical miRNAs that act coordinately to target pathways of functionally related genes. This work exposes the complexity of the miRNA-transcriptome, and helps explain a major miRNA paradox: how specific regulation of biological processes can occur with predominantly non-specific miRNA-mRNA interactions. 6 samples submitted, all replicates of Human Placenta total RNA, Ambion The miRNA-Seq data have been submitted to the short read archive under SRA number SRP006043: http://www.ncbi.nlm.nih.gov/sra?term= SRP006043
Project description:Many microRNAs (miRNAs) exist alongside abundant miRNA isoforms (isomiRs), most of which arise from post-maturation sequence modifications, such as 3’ uridylation. However, the ways in which these sequence modifications affect miRNA function remain poorly understood. Here, using human miR-27a in cell lines as a model, we have discovered that a nonfunctional target site unable to base pair extensively with the miRNA seed sequence can regain function when an upstream adenosine is able to base-pair with a post-transcriptionally added uridine in the miR-27a tail. This Tail-U-Mediated Repression (TUMR) is abolished in cells lacking the uridylation enzymes TUT4 and TUT7, indicating that uridylation alters miRNA function by modulating target recognition. We identified a set of non-canonical targets in human cells that are specifically regulated by uridylated miR-27a. We provide evidence that TUMR expands the targets of other endogenous miRNAs. Our study reveals a function for uridylated isomiRs in regulating non-canonical miRNA targets.