Project description:T cells, crucial for immune regulation, risk malfunction leading to immune deficiencies or autoimmune diseases. Understanding the molecular cycle of T cell activation is vital for potential therapeutic interventions. Activation remodels the cellular transcriptome and proteome, impacting metabolism and protein synthesis pathways. The human genome encodes microRNAs (miRNAs), regulating hundreds of protein-coding mRNAs through translational repression and mRNA decay. While mRNA degradation is terminal, translational repression is reversible, allowing rapid responses to internal or external cues. In this study, we investigated changes in the miRNA repertoire and their impact on translational repression and mRNA degradation during T cell activation using high-throughput techniques. Our findings reveal that miRNAs induced upon T cell activation clear their targets through multiple pathways, with some following the canonical path of mRNA degradation and others initiating translational repression before mRNA degradation.

Project description:T cells, crucial for immune regulation, risk malfunction leading to immune deficiencies or autoimmune diseases. Understanding the molecular cycle of T cell activation is vital for potential therapeutic interventions. Activation remodels the cellular transcriptome and proteome, impacting metabolism and protein synthesis pathways. The human genome encodes microRNAs (miRNAs), regulating hundreds of protein-coding mRNAs through translational repression and mRNA decay. While mRNA degradation is terminal, translational repression is reversible, allowing rapid responses to internal or external cues. In this study, we investigated changes in the miRNA repertoire and their impact on translational repression and mRNA degradation during T cell activation using high-throughput techniques. Our findings reveal that miRNAs induced upon T cell activation clear their targets through multiple pathways, with some following the canonical path of mRNA degradation and others initiating translational repression before mRNA degradation.

Project description:Entry into and exit from mitosis is driven by precisely-timed changes in protein abundance, and involves transcriptional regulation and protein degradation. However, the role of translational regulation in modulating cellular protein content during mitosis remains poorly understood. Here, using ribosome profiling, we show that translational, rather than transcriptional regulation is the dominant mechanism for modulating protein synthesis at mitotic entry. The vast majority of regulated mRNAs are translationally repressed, which contrasts previous findings of selective mRNA translational activation at mitotic entry. One of the most pronounced translationally repressed genes in mitosis is Emi1, an inhibitor of the anaphase promoting complex (APC), which is degraded during mitosis. We show that Emi1 degradation is insufficient for full APC activation and that simultaneous translational repression is required. These results provide a genome-wide view of protein translation during mitosis and suggest that translational repression may be used to ensure complete protein inactivation Ribosome profiling and mRNA-seq from 3 time points in the cell cycle

Project description:miRNAs regulate the expression of its targets genes by promoting mRNA degradation and translational repression. The goal of this study is to perform RNA-Seq in control or miR-148a-expressing WEHI-231 cell lines for the identification of miR-148a target genes.

Project description:MicroRNAs (miRNAs) regulate target mRNAs through a combination of translational repression and mRNA destabilization, with mRNA destabilization dominating at steady state in the few contexts examined globally. Here, we extend the global steady-state measurements to many additional mammalian contexts and find that regardless of the miRNA, cell type, growth condition or translational state, mRNA destabilization explains most (70% to >90%) miRNA-mediated repression. We also determine the relative dynamics of translational repression and mRNA destabilization for endogenous mRNAs as a miRNA is induced. Although translational repression occurs rapidly, its effect on gene expression is relatively weak, such that by the time consequential repression ensues, the effect of mRNA destabilization dominates. These results add to the fundamental understanding of miRNAs, imply that consequential miRNA-mediated repression is largely irreversible and simplify future studies, dramatically extending the known contexts and time points for which monitoring mRNA changes captures most of the direct miRNA effects. 6 samples from a variety of primary cell types

Project description:miRNAs regulate the expression of its targets genes by promoting mRNA degradation and translational repression. The goal of this study is to perform RNA-Seq in control or miR-148a-expressing WEHI-231 cell lines for the identification of miR-148a target genes. WEHI-control and WEHI-miR-148a cells were stimulated with anti-IgM (2 ug/ml) for 14 h. Total RNA was extracted, enriched for polyA-containing RNAs and submitted to RNA-Seq.

Project description:Entry into and exit from mitosis is driven by precisely-timed changes in protein abundance, and involves transcriptional regulation and protein degradation. However, the role of translational regulation in modulating cellular protein content during mitosis remains poorly understood. Here, using ribosome profiling, we show that translational, rather than transcriptional regulation is the dominant mechanism for modulating protein synthesis at mitotic entry. The vast majority of regulated mRNAs are translationally repressed, which contrasts previous findings of selective mRNA translational activation at mitotic entry. One of the most pronounced translationally repressed genes in mitosis is Emi1, an inhibitor of the anaphase promoting complex (APC), which is degraded during mitosis. We show that Emi1 degradation is insufficient for full APC activation and that simultaneous translational repression is required. These results provide a genome-wide view of protein translation during mitosis and suggest that translational repression may be used to ensure complete protein inactivation

Project description:MicroRNAs (miRNAs) regulate target mRNAs through a combination of translational repression and mRNA destabilization, with mRNA destabilization dominating at steady state in the few contexts examined globally. Here, we extend the global steady-state measurements to many additional mammalian contexts and find that regardless of the miRNA, cell type, growth condition or translational state, mRNA destabilization explains most (70% to >90%) miRNA-mediated repression. We also determine the relative dynamics of translational repression and mRNA destabilization for endogenous mRNAs as a miRNA is induced. Although translational repression occurs rapidly, its effect on gene expression is relatively weak, such that by the time consequential repression ensues, the effect of mRNA destabilization dominates. These results add to the fundamental understanding of miRNAs, imply that consequential miRNA-mediated repression is largely irreversible and simplify future studies, dramatically extending the known contexts and time points for which monitoring mRNA changes captures most of the direct miRNA effects.

Project description:DDX6 decouples translational repression from RNA degradation of miRNA targets [QuantSeq mRNA]

Project description:In cell senescence, cultured cells cease proliferating and acquire aberrant gene expression patterns. MicroRNAs (miRNAs) modulate gene expression through translational repression or mRNA degradation, and have been implicated in senescence. We have used deep sequencing to carry out a comprehensive survey of miRNA expression and its involvement in cell senescence. Informatic analysis of small RNA sequence datasets from young and senescent IMR90 human fibroblasts identifies many known miRNAs, and a small number of novel miRNAs, that are regulated (either up or down) with cell senescence. Comparison with mRNA expression profiles revealed potential mRNA targets of the senescence-regulated miRNAs. The target mRNAs are enriched for genes involved in biological processes associated with cell senescence. This result greatly extends existing information on the role of miRNAs in cell senescence, and is consistent with miRNAs having a causal role in the process. Comprehensive survey of miRNA from young and senescent IMR90 fibroblasts using deep sequencing