Project description:It is widely accepted that long-term changes in synapse structure and function are mediated by rapid activity-dependent gene transcription and new protein synthesis. A growing amount of evidence suggests that the microRNA (miRNA) pathway plays an important role in coordinating these processes. Despite recent advances in this field, there remains a critical need to identify specific activity-regulated miRNAs as well as their key messenger RNA (mRNA) targets. To address these questions, we used the larval Drosophila melanogaster neuromuscular junction (NMJ) as a model synapse in which to identify novel miRNA-mediated mechanisms that control activity-dependent synaptic growth. First, we developed a screen to identify miRNAs differentially regulated in the larval CNS following spaced synaptic stimulation. Surprisingly, we identified five miRNAs (miRs-1, -8, -289, -314, and -958) that were significantly downregulated by activity. Neuronal misexpression of three miRNAs (miRs-8, -289, and -958) suppressed activity-dependent synaptic growth suggesting that these miRNAs control the translation of biologically relevant target mRNAs. Functional annotation cluster analysis revealed that putative targets of miRs-8 and -289 are significantly enriched in clusters involved in the control of neuronal processes including axon development, pathfinding, and growth. In support of this, miR-8 regulated the expression of a wingless 3M-bM-^@M-^YUTR (wg 3M-bM-^@M-^Y untranslated region) reporter in vitro. Wg is an important presynaptic regulatory protein required for activity-dependent axon terminal growth at the fly NMJ. In conclusion, our results are consistent with a model where key activity-regulated miRNAs are required to coordinate the expression of genes involved in activity-dependent synaptogenesis. Three technical replicates (each in raw data) of three biological replicates of wild-type (CantonS) larvae in two treatment groups: (1) 5x spaced high K; (2) or 0x mock stimulation.

Project description:It is widely accepted that long-term changes in synapse structure and function are mediated by rapid activity-dependent gene transcription and new protein synthesis. A growing amount of evidence suggests that the microRNA (miRNA) pathway plays an important role in coordinating these processes. Despite recent advances in this field, there remains a critical need to identify specific activity-regulated miRNAs as well as their key messenger RNA (mRNA) targets. To address these questions, we used the larval Drosophila melanogaster neuromuscular junction (NMJ) as a model synapse in which to identify novel miRNA-mediated mechanisms that control activity-dependent synaptic growth. First, we developed a screen to identify miRNAs differentially regulated in the larval CNS following spaced synaptic stimulation. Surprisingly, we identified five miRNAs (miRs-1, -8, -289, -314, and -958) that were significantly downregulated by activity. Neuronal misexpression of three miRNAs (miRs-8, -289, and -958) suppressed activity-dependent synaptic growth suggesting that these miRNAs control the translation of biologically relevant target mRNAs. Functional annotation cluster analysis revealed that putative targets of miRs-8 and -289 are significantly enriched in clusters involved in the control of neuronal processes including axon development, pathfinding, and growth. In support of this, miR-8 regulated the expression of a wingless 3M-bM-^@M-^YUTR (wg 3M-bM-^@M-^Y untranslated region) reporter in vitro. Wg is an important presynaptic regulatory protein required for activity-dependent axon terminal growth at the fly NMJ. In conclusion, our results are consistent with a model where key activity-regulated miRNAs are required to coordinate the expression of genes involved in activity-dependent synaptogenesis. larval CNS of UAS-ChR2 x C380-Gal4 following synaptic stimulation

Project description:Increasing evidence suggests that CRS is a heterogeneous group of sinus disorders involving overlapping but distinct disease entities.The factors leading to different CRS phenotypes remain enigmatic. The role of miRNAs in the regulation of immunological and inflammatory processes is beginning to emerge.Thus, we examined microRNAs expression profiles in eosinophilic CRSwNP adn CRSsNP. Compared with controls, 31 differentially expressed miRNAs (30 downregulated and 1 upregulated miRNAs) in eosinophilic CRSwNP and 4 differentially expressed miRNAs (2 downregulated and 2 upregulated miRNAs) in CRSsNP were indentified. Real time RT-PCR was subsequently performed to verify the miRNA microarray result. Examination of miRNAs expression in eosinophilic CRSwNP and CRSsNP

Project description:MIcroRNA expression profiling of primary murine splenic dendritic cells (Flt3L expanded) comparing untreated cells to cells infected with Influenza A or stimulated with polyI:C in vitro. Three-condition experiment, Influenza A/PR/8/34 virus MOI=10 vs polyI:C 30 ug/mL vs. mock treated; RNA collected after 8 hours. 3 Independent biological replicates from cells prepared on different days. One replicate per array.

Project description:Gene expression in mammalian testis undergoing spermatogenesis is under strict post transcriptional regulation and microRNAs are known to play a role in this regulation. Considering the time window of first wave of spermatogenesis, we did a microarray profiling of total testicular microRNAs in mouse and found several significant patterns of variable expression of these molecules during the different stages analyzed here. Mouse testis tissue were taken at three stages, 8 days, 16 days and 24 days, during first wave of spermatogenesis for RNA extraction and hybridization on Locked Nucleic Acid(LNA) technology based Exiqon microarray platform. We included two biological replicates per age group and comparisons were done between the samples with respect to their hybridization to the 'reference' sample which had all the six samples pooled together.

Project description:Background: TrkB-T1 is a BDNF receptor lacking a tyrosine kinase domain that is highly expressed in astrocytes and regulates BDNF-evoked calcium transients. Previous studies indicate that downregulation of TrkB-T1 in frontal cortex may be involved in neurobiological processes underlying suicide. Methods: In a microarray screening study (N=8), we interrogated all known microRNA in the frontal cortex of suicide completers with low expression of TrkB-T1 and normal controls. These findings were validated and followed up in a larger sample of cases and controls (N=55) Functional analyses included microRNA silencing, microRNA overexpression and luciferase assays to investigate specificity and to validate interactions between differentially expressed microRNA and TrkB-T1 Results: microRNAs Hsa-miR-185* and Hsa-miR-491-3p were upregulated in suicide completers with low expression of TrkB.T1 (Pnominal: 9.10-5 and 1.8.10-4 respectively; FDR-corrected p=0.031). Bioinformatic analyses revealed five putative binding sites for the DiGeorge syndrome linked microRNA Hsa-miR-185*in the 3M-bM-^@M-^YUTR of TrkB-T1, but none for Hsa-miR-491-3P. The increase of Hsa-miR-185* in frontal cortex of suicide completers was validated then confirmed in a larger, randomly selected group of suicide completers, where an inverse correlation between Hsa-miR-185* and TrkB-T1 expression was observed ( R=-0.404; p=0.002). Silencing and overexpression studies performed in human cell lines confirmed the inverse relationship between hsa-mir-185* and trkB-T1 expression. Luciferase assays demonstrated that Hsa-miR-185* binds to sequences in the 3M-bM-^@M-^YUTR of TrkB-T1. Conclusion: These results suggest that an increase of Hsa-miR-185* expression levels regulates, at least in part, the TrkB-T1 decrease observed in the frontal cortex of suicide completers and further implicate the 3MB 22q11 region in psychopathology. The microarray analysis consists in to compare the microRNA profile of four suicide completers with low TrkB-T1 expression level and four controls. Each RNA extract was labeled with Hy3 and hybridyzed with a reference sample labeled with Hy5. The reference sample was a pool of the eight RNA samples

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:The purpose of this study was to determine the miRNA expression profile of in vitro differentiation of human skeletal muscle cells and to couple changes in individual miRNA expression to transcriptional output of target genes. miRNA expression profiling at six different time points during the in vitro differentiation process of human skeletal muscle cells from six subjects. RNA was harvested from myoblasts before induction of differentiation and at every other day for 10 following days. Temporal, time-course design with paired analysis (6 subjects). Biological replicates: 6 at day 0, 6 at day 2, 6 at day 4, 6 at day 6, 6 at day 8, and 5 at day 10. One replicate vs common reference RNA pool per array.

Project description:The salamander microRNA expression between mid-bud limb regenerating blastemas (17 days post amputation) and non-regenerating stump tissues was compared by microarray analysis. LC Sciences arrays: Six paired samples were analyzed: three mid-bud 17dpa blastemas (bl), and three non-regenerating stumps (st). Three arrays were hybridized comparing two paired samples each time. Biological dye-swaps were made by labeling bl samples once with Cy3 and twice with Cy5; st samples were labeled accordingly twice with Cy5 and once with Cy3. Multiple arrays averaged into a single Sample record. Supplementary files: GSE29727_LC_MultiArray_SimpleNormalizedData.txt.gz GSE29727_LC_signal_ratio_mean_SD.txt.gz GSE29727_LC_t-Test_st-vs-bl.txt.gz Exiqon arrays: Six paired samples were analyzed: three mid-bud 17dpa blastemas (bl), and three non-regenerating stumps (st). Six arrays were hybridized comparing each sample labeled with Hy3 against a common reference sample made by pooling all the samples and labeling it with Hy5. Multiple arrays not averaged, represented as multiple Sample records. Supplementary file: GSE29727_Exiqon_matrix_complete.txt

Project description:miRNA profiling of Jurkat T-ALL cells after knockdown with two control shRNAs and two shRNAs targeting TAL1 to identify miRNAs that are regulated by TAL1 miRNA profiling using Exiqon arrays 48hrs after transduction of Jurkat cells with two control shRNAs (pLKO1-GFP and pLKO1-LUCIFERASE) vs two shRNAs targeting TAL1 (pLKO1-shRNA1 and pLKO1-shRNA2). Biological duplicates per shRNA. One replicate per array.Total of 8 arrays.