Project description:Target mRNAs induce tailing and trimming of Ago2-loaded miRNAs in neurons

Project description:This study compares the transcripts bound to BORIS in neural progenitor cells and cells differentiated for 6 days into young neurons We present expression profiles for neural progenitor cells (arrays hybridised in triplicate) and in young neurons (arrays hybridised in duplicate). Immunoprecipitated BORIS-mRNA complexes were used to assess the association of BORIS with target mRNAs in neural progenitor cells and in young neurons (both arrays hybridised in duplicate).

Project description:We show that target mRNAs trigger the non-templated addition of nucleotides (mainly adenosines and uridines) and shortening of their cognate miRNAs in primary hippocampal neurons. The induced effect is observable both in total RNA and in Ago2-associated RNA, demonstrating that the process is initiated in Ago2 bound miRNAs. Illumina Small RNA sequencing was performed on rat hippocampal neurons infected with different target mRNAs in different conditions. The data includes 3 independent experiments: 1. Hippocampal neurons (DIV15) 6 days after transducing them with target mRNAs (driven by the Synapsin promoter) against different miRNAs. Samples are titled "Syn-Target". Samples transduced with targets containing extensive complementarity are labeled "Ext" and those with Seed complementarity are labeled "Seed". 2. Hippocampal neurons (DIV16) 7 days after transducing them with an inducible target mRNA against miR-132, and inducing for different times with Doxycycline. Samples are titled "Time-course" 3. Hippocampal neurons (DIV16) 7 days after co-transducing them with FLAG/HA-Ago2 plus an inducible target mRNA against miR-132, and inducing them for different times with Doxycycline. Samples are titled "Time-course_Ago2"

Project description:Morphogenesis of the mammalian neural tube (NT) is reliant on precise, spatio-temporal expression of numerous genes and coordinated interaction of signal transduction and gene regulatory networks, disruption of which may contribute to the etiology of neural tube defects (NTDs). MicroRNAs (miRNAs) as well as their downstream messenger RNA (mRNA) targets are key modulators of cell and tissue differentiation. To define potential roles of miRNAs and mRNAs in development of the murine neural tube (NT), total RNA preparations from gestation day (GD)-8.5, -9.0 and -9.5 (crtitcal period of NT developemnt) mouse embryos were used to hybridize both microRNA arrays and messenger RNA arrays, to identify miRNAs and mRNAs co-expressed in the same developing NT tissue samples.

Project description:Morphogenesis of the mammalian neural tube (NT) is reliant on precise, spatio-temporal expression of numerous genes and coordinated interaction of signal transduction and gene regulatory networks, disruption of which may contribute to the etiology of neural tube defects (NTDs). MicroRNAs (miRNAs) as well as their downstream messenger RNA (mRNA) targets are key modulators of cell and tissue differentiation. To define potential roles of miRNAs and mRNAs in development of the murine neural tube (NT), total RNA preparations from gestation day (GD)-8.5, -9.0 and -9.5 (crtitcal period of NT developemnt) mouse embryos were used to hybridize both microRNA arrays and messenger RNA arrays, to identify miRNAs and mRNAs co-expressed in the same developing NT tissue samples.

Project description:SYNCRIP, a member of the cellular heterogeneous nuclear ribonucleoprotein (hnRNP) family of RNA binding proteins, regulates various aspects of neuronal development and plasticity. Although SYNCRIP has been identified as a component of cytoplasmic RNA granules in dendrites of mammalian neurons, only little is known about the specific SYNCRIP target mRNAs that mediate its effect on neuronal morphogenesis and function. Here, we present a comprehensive characterization of the cytoplasmic SYNCRIP mRNA interactome using iCLIP in primary rat cortical neurons. We identify hundreds of bona fide SYNCRIP target mRNAs, many of which encode for proteins involved in neurogenesis, neuronal migration and neurite outgrowth. From our analysis, the stabilization of mRNAs encoding for components of the microtubule network, such as doublecortin (Dcx), emerges as a novel mechanism of SYNCRIP function in addition to the previously reported control of actin dynamics. Furthermore, we found that SYNCRIP interacts with miRISC and synergizes with pro-neural miRNAs, such as miR-9. Based on our findings, we propose a model whereby SYNCRIP promotes early neuronal differentiation by a two-tier mechanism involving the stabilization of pro-neural mRNAs by direct 3’UTR interaction and the repression of anti-neural mRNAs in a complex with neuronal miRISC. Together, our findings provide a rationale for future studies investigating the function of SYNCRIP in mammalian brain development and disease.

Project description:Studying chemical disturbances during neural differentiation of mES cells has been established as an alternative in vitro testing approach for the identification of developmental toxicants. miRNAs represent a class of small regulatory RNA molecules, which bind to target mRNAs thereby repressing their translation. Many studies have shown an essential role of miRNAs in regulation of gene expression during development and ESC differentiation. Thus, neural differentiation of ESC in vitro allows investigating the role of miRNAs in chemical-mediated developmental toxicity. We analyzed the expression of miRNAs and transcriptomics changes during neural differentiation of mESC exposed to the developmental neurotoxicant sodium valproate (VPA). A total of 110 miRNAs and 377 mRNAs were identified differently expressed in neural differentiating mES cells under VPA treatment (300µM) compared to solvent control on day 16 of differentiation. Analysis of miRNA expression revealed that valproate switches the lineage specification from neural to myogenic differentiation (upregulation of muscle-enriched miRNAs mir-206, mir-133a and mir-10a and downregulation of neuro-specific miRNAs mir-124a, mir-128 and mir-137). The findings on the miRNA level could be confirmed on mRNA level (induction of expression of myogenic regulatory factors (MRFs) as well as muscle specific genes (Actc1, calponin, myosin light chain, asporin, decorin) and repression of genes involved in neurogenesis (Otx1 and 2, Zic3, 4, 5)) as well as morphologically by immunocytochemistry. The observed results were VPA specific and most probably due to inhibition of histone deacetylase (HDAC) activity of VPA for two reasons: (i) we did not observe any induction of muscle specific miRNAs in neural differentiating ES cells exposed to the unrelated developmental neurotoxicant sodium arsenite; (ii) expression of muscle specific mir-206 and muscle enriched mir-10a was similarly increased in cells exposed to a structurally different HDAC inhibitor, trichostatin A (TSA). Furthermore, using our in vitro cell system we could confirm an aberrant expression of known VPA target genes and genes involved in neural tube closure. We conclude that miRNA expression profiling is a suitable molecular endpoint for developmental neurotoxicity. Observed lineage shift into myogenesis, where miRNAs play a significant role, could be a major developmental neurotoxical mechanism of VPA. We used microarray approach to identify altered miRNA expression in neural differentiated mES cells exposed to two known developmental neurotxicants and epigenetic active substances, sodium valproate (VPA) and sodium arsenite (As) mES cells line W4 were induced to differnetiate into neurons under exposure to VPA for 16 days. RNA for microarrays was collected on day 16 of differentiation from three biological replicates of solvent control (PBS) and VPA treated cells.

Project description:Studying chemical disturbances during neural differentiation of mES cells has been established as an alternative in vitro testing approach for the identification of developmental toxicants. miRNAs represent a class of small regulatory RNA molecules, which bind to target mRNAs thereby repressing their translation. Many studies have shown an essential role of miRNAs in regulation of gene expression during development and ESC differentiation. Thus, neural differentiation of ESC in vitro allows investigating the role of miRNAs in chemical-mediated developmental toxicity. We analyzed the expression of miRNAs and transcriptomics changes during neural differentiation of mESC exposed to the developmental neurotoxicant sodium valproate (VPA). A total of 110 miRNAs and 377 mRNAs were identified differently expressed in neural differentiating mES cells under VPA treatment (300µM) compared to solvent control on day 16 of differentiation. Analysis of miRNA expression revealed that valproate switches the lineage specification from neural to myogenic differentiation (upregulation of muscle-enriched miRNAs mir-206, mir-133a and mir-10a and downregulation of neuro-specific miRNAs mir-124a, mir-128 and mir-137). The findings on the miRNA level could be confirmed on mRNA level (induction of expression of myogenic regulatory factors (MRFs) as well as muscle specific genes (Actc1, calponin, myosin light chain, asporin, decorin) and repression of genes involved in neurogenesis (Otx1 and 2, Zic3, 4, 5)) as well as morphologically by immunocytochemistry. The observed results were VPA specific and most probably due to inhibition of histone deacetylase (HDAC) activity of VPA for two reasons: (i) we did not observe any induction of muscle specific miRNAs in neural differentiating ES cells exposed to the unrelated developmental neurotoxicant sodium arsenite; (ii) expression of muscle specific mir-206 and muscle enriched mir-10a was similarly increased in cells exposed to a structurally different HDAC inhibitor, trichostatin A (TSA). Furthermore, using our in vitro cell system we could confirm an aberrant expression of known VPA target genes and genes involved in neural tube closure. We conclude that miRNA expression profiling is a suitable molecular endpoint for developmental neurotoxicity. Observed lineage shift into myogenesis, where miRNAs play a significant role, could be a major developmental neurotoxical mechanism of VPA. We used microarray approach to identify altered miRNA expression in neural differentiated mES cells exposed to two known developmental neurotxicants and epigenetic active substances, sodium valproate (VPA) and sodium arsenite (As) mES cells line W4 were induced to differnetiate to neurons under exposure to VPA and As for 16 days. RNA for microarrays was collected on day 16 of differentiation from three biological replicates of solvent controls (PBS was used as a solvent for VPA and H20 for As) or substance treated cells.

Project description:Background: MicroRNAs (miRNAs) are short non-coding RNAs predicted to regulate one third of protein-coding genes via mRNA targeting. In conjunction with key transcription factors, such as the repressor REST (RE1 silencing transcription factor), miRNAs play crucial roles in neurogenesis, which requires a highly orchestrated program of gene expression to ensure the appropriate development and function of diverse neural cell types. Whilst previous studies have highlighted select groups of miRNAs during neural development, there remains a need for amenable models in which miRNA expression and function can be analyzed over the duration of neurogenesis. Principal Findings: We performed large-scale expression profiling of miRNAs in human NTera2/D1 (NT2) cells during retinoic acid (RA)-induced transition from progenitors to fully differentiated neural phenotypes. Our results revealed dynamic changes of miRNA patterns, resulting in distinct miRNA subsets that could be linked to specific neurodevelopmental stages. Moreover, the cell-type specific miRNA subsets were very similar in NT2-derived differentiated cells and human primary neurons and astrocytes. Further analysis identified miRNAs as putative regulators of REST, as well as candidate miRNAs targeted by REST. Finally, we confirmed the existence of two predicted miRNAs; pred-MIR191 and pred-MIR222 associated with SLAIN1 and FOXP2, respectively, and provided some evidence of their potential co-regulation. Conclusions: In the present study, we demonstrate that regulation of miRNAs occurs in precise patterns indicative of their roles in cell fate commitment, progenitor expansion and differentiation into neurons and glia. Furthermore, the similarity between our NT2 system and primary human cells suggests their roles in molecular pathways critical for human in vivo neurogenesis. The experiment consists of a total of 51 arrays: 29 retinoic acid time series arrays (0,2,4,6,8,12,14,21 and 28 days), 2 each of NT2-derived neurons and astrocytes, 12 primary human fetal astrocytes, 3 primary human embryonic astrocytes and 3 primary human neurons. Each condition has a minimum of 2 biological replicates. The samples were compared as single channel experiments. NOTE: The raw data files were submitted as generated in Quantarray with 2 channels, but due to issues with the control sample dye (Cy5 on Channel 1), only the Channel 2 (Cy3) data was analysed.

Project description:Here, we have addressed the mechanisms that determine genesis of the correct numbers of neurons during development, focusing upon the embryonic cortex. We identify in neural precursors a repressive complex involving eIF4E1 and its binding partner 4E-T that coordinately represses translation of proteins that determine neurogenesis. This eIF4E1/4E-T complex is present in granules with the processing body proteins Lsm1 and Rck, and disruption of this complex causes premature and enhanced neurogenesis and neural precursor depletion. Analysis of the 4E-T complex shows that it is highly enriched in mRNAs encoding transcription factors and differentiation-related proteins. These include the proneurogenic bHLH mRNAs, which colocalize with 4E-T in granules, and whose protein products are aberrantly upregulated following knockdown of eIF4E, 4E-T, or processing body proteins. Thus, neural precursors are transcriptionally primed to generate neurons, but an eIF4E/4E-T complex sequesters and represses translation of proneurogenic proteins to determine appropriate neurogenesis. We obtained 3 biological replicates of IgG-bound RNA, 4E-T-bound RNA, and cooresponding total RNA input from mouse E12-13 cortices. RNA samples were analyzed on the Affymetrix Mouse Gene 2.0 ST Arrays.