Project description:We identify a brain-specific microRNA—miR-128—that represses Nonsense Mediated mRNA Decay (NMD) and thereby controls batteries of transcripts in neural cells. miR-128 represses NMD by targeting the RNA helicase UPF1 and the exon-junction complex core component MLN51. We employed exon arrays for this analysis, as this platform detects expression levels of individual exons and thus allows detection of not only differentially expressed transcripts (DETs), but also alternative isoform transcripts (AITs). The latter is particularly relevant to our study because alternative RNA processing events (e.g., RNA splicing, alternative promoter usage, and alternative polyadenylation-site usage) often place a translation termination codon in a premature context and thereby trigger NMD.

Project description:Throughout postnatal life in mammals, neural stem cells (NSCs) are located in the subventricular zone (SVZ) of the lateral ventricles. The greatest diversity of neuronal and glial lineages they generate occurs during early postnatal life in a region-specific manner. In order to evaluate potential heterogeneity in the NSC pool, we microdissected the dorsal and lateral SVZ at different postnatal ages and isolated NSCs and their immediate progeny based on their expression of Hes5-EGFP/Prominin1 and Ascl1-EGFP, respectively. Whole genome comparative transcriptome analysis revealed transcriptional regulators as major hallmarks that sustain postnatal SVZ regionalization. Manipulation of single genes encoding for locally enriched transcription factors influenced NSC specification indicating that the fate of regionalized postnatal SVZ NSCs can be readily modified . These findings reveal functional heterogeneity of NSCs in the postnatal SVZ and provide targets to recruit region-specific lineages in regenerative contexts. Microarrays of neural stem cells, early progenitors and the tissue from subregions of the subventricular zone were compiled to screen for the full extent of heterogeneity in this region during postnatal life. Spatially distinct regions of the developing forebrain subventricular zone (SVZ) aged at P4, P8 and P11 were microdissected in RNAse free/sterile conditions. Mice expressing Ascl1-EGFP in the SVZ were used to aid accurate microdissection of the dorsal and lateral wall of each of the studied time points as per our previous publications characterizing this method. As well as at the whole microdomain level, additionally, NSCs (Hes5-EGFP+/Prom1+) and early progenitors (Ascl1-EGFP+) from each microdomain were further isolated by FAC sorting methods. This was to provide a comprehensive gene expression analysis at the tissue level and at the cellular level. Generally, 1 litter was used to yield 1 'n' number of replicates. A total of 23 affymetrix analysis were performed.

Project description:Nonsense-mediated mRNA decay (NMD) is a eukaryotic surveillance pathway that recognizes aberrant transcripts arising from mutations and transcriptional mistakes. Moreover, differential transcript processing such as alternative precursor mRNA splicing (AS) can generate NMD substrates, however, the extent of coupled AS and NMD remained unclear. To investigate NMD targeting of AS variants, we performed transcriptome-wide splicing studies using Arabidopsis thaliana single and double mutants in the NMD factor homologues UPF1 and UPF3, as well as samples treated with the translation inhibitor cycloheximide (CHX). Our analyses revealed that at least 17.5% of all multi-exon, protein-coding genes produce splicing variants of all major types that are targeted by NMD, with a significant fraction originating from the splicing of cryptic introns. Furthermore, accumulation of many intron-retained mRNAs in the mutants, but not in response to CHX suggests the action of distinct routes of NMD with variable impact of translation. Importantly, 92.3% of the NMD-responsive mRNAs exhibit classical NMD-eliciting features, supporting their authenticity as direct targets. NMD-dependent AS variants are linked to diverse biological functions, including the poison exon-mediated regulation of signaling and posttranslational protein modification components. In addition to mRNAs, numerous non-coding RNAs as well as newly identified transcripts derived from intergenic regions were shown to be NMD responsive. In summary, our comprehensive analysis of AS-coupled NMD provides strong evidence for a major function of this pathway in shaping the transcriptome, having fundamental implications in gene regulation and quality control of transcript processing steps in higher eukaryotes. Comparison of gene expression and alternative splicing patterns in control and nonsense-mediated decay (NMD)-impaired Arabidopsis seedlings

Project description:Across life neural stem cells (NSCs) generate new neurons in the mammalian brain through asymmetric neurogenic and self-renewing cell divisions. However, the cellular mechanisms underlying NSC asymmetry remain unknown. Using fluorescence loss in photobleaching (FLIP) we here show that NSCs in vitro and within the developing forebrain generate a lateral diffusion barrier during cell division resulting in asymmetric segregation of cellular components. The strength of the diffusion barrier is dynamically regulated with age and depends on the proper function of lamin-associated nuclear envelope constituents. Strikingly, age-associated or experimental impairment of the diffusion barrier disrupts asymmetric segregation of damaged proteins, a product of aging. Thus, the data presented here identify a mechanism how age is asymmetrically distributed during somatic stem cell division. For microarray analysis we analysed gene expression in cells derived from the hippocampi of 6 week old (young) or 9 month old (old) male C57BL/6JRj mice. 6 samples were analyzed YoungNSC, 3 replicates OldNSC, 3 replicates

Project description:Nonsense-mediated mRNA decay (NMD) is essential for removing premature termination codon (PTC)-containing transcripts from cells. Studying the NMD pathway in model organisms can help to elucidate the NMD mechanism of humans and improves our understanding of how this biologically important process has evolved. Protozoa are among the earliest branching eukaryotes. Their NMD mechanism is poorly understood and may be primordial. We demonstrate that highly conserved Upf proteins (Upf1a, Upf2, and Upf3) are involved in the NMD pathway of the ciliate, Tetrahymena thermophila. We further show that a novel protozoa-specific nuclease, Smg6L, is responsible for destroying many NMD-targeted transcripts. The transcriptome-wide identification and characterization of NMD-targeted transcripts in vegetative Tetrahymena cells showed that many have exon–exon junctions downstream of the termination codon. However, Tetrahymena homologs of exon junction complex (EJC) core components do not form a complex and are dispensable for NMD, suggesting that NMD is EJC independent in this early branching eukaryote.

Project description:Alternative first exon isoforms are frequently observed among transcriptomes derived from different developmental stages of eukaryotes. Stage-specific alternative first exon (SAFE) transcripts are usually involved in the regulation of cell development in spatiotemporal manners. The transcriptome analysis for RNA-seq data make it possible to identify specifically used first exons in mouse embryonic stem cells (mESCs) compared to somatic cells, just like tail tip fibroblasts (TTFs). In this study, we identify 128 genes producing SAFE isoforms in mESCs.

Project description:Transcriptional profiling of mouse postnatal SVZ NSCs comparing WT NSCs with KO NSCs under proliferating/undifferentiated states as well as differentiating conditions. Goal was to determine Dnmt3a-dependent gene expression changes in postnatal SVZ NSCs Two-condition experiment with a dye-swap design, WT NSCs vs. KO NSCs. Biological replicates: 4 replicates under proliferating/undifferentiation conditions, 2 replicates under differentiating conditions.

Project description:Primitive neural stem cells (NSCs) could be derived from pluripotent mouse embryonic stem (ES) cells, and then differentiate into definitive-type neural stem cells which resemble NSCs obtained from the central nervous system. Hence, primitive NSCs define an early stage of neural induction and provide a model to understand the mechanism that controls initial neural commitment. In this study, we performed microarray assay to analyze the global transcriptional profiles in mouse ES cell-derived primitive and definitive NSCs and to depict the molecular changes during the multi-staged neural differentiation process. Primitive NSCs derived directly from ESCs in Lif (p-NSC_L), primitive NSCs that were sub-cultured in the presence of Lif and FGF (p-NSC_LF), as well as definitive NSCs derived from primitive NSCs in medium containing FGF and EGF, were collected for RNA extraction and hybridization on Affymetrix microarrays. Mouse ESCs and NSCs obtained from mouse embryonic brain (E11.5) were included for controls. For each cell type, we collected two biological replicate samples for microarray analysis.

Project description:Nonsense-mediated mRNA decay (NMD) is a eukaryotic surveillance pathway that recognizes aberrant transcripts arising from mutations and transcriptional mistakes. Moreover, differential transcript processing such as alternative precursor mRNA splicing (AS) can generate NMD substrates, however, the extent of coupled AS and NMD remained unclear. To investigate NMD targeting of AS variants, we performed transcriptome-wide splicing studies using Arabidopsis thaliana single and double mutants in the NMD factor homologues UPF1 and UPF3, as well as samples treated with the translation inhibitor cycloheximide (CHX). Our analyses revealed that at least 17.5% of all multi-exon, protein-coding genes produce splicing variants of all major types that are targeted by NMD, with a significant fraction originating from the splicing of cryptic introns. Furthermore, accumulation of many intron-retained mRNAs in the mutants, but not in response to CHX suggests the action of distinct routes of NMD with variable impact of translation. Importantly, 92.3% of the NMD-responsive mRNAs exhibit classical NMD-eliciting features, supporting their authenticity as direct targets. NMD-dependent AS variants are linked to diverse biological functions, including the poison exon-mediated regulation of signaling and posttranslational protein modification components. In addition to mRNAs, numerous non-coding RNAs as well as newly identified transcripts derived from intergenic regions were shown to be NMD responsive. In summary, our comprehensive analysis of AS-coupled NMD provides strong evidence for a major function of this pathway in shaping the transcriptome, having fundamental implications in gene regulation and quality control of transcript processing steps in higher eukaryotes.

Project description:Brief expression of pluripotency-associated factors such as OCT4, KLF4, SOX2 and c-MYC (OKSM), in combination with differentiation-inducing signals, was reported to trigger transdifferentiation of fibroblasts into alternative cell types. Here, we show that OKSM expression gives rise to both induced pluripotent stem cells (iPSCs) and iNSCs under conditions that were previously shown to induce only NSC transdifferentiation. Fibroblast-derived iNSC colonies silenced retroviral transgenes and reactivated silenced X chromosomes, both hallmarks of pluripotent stem cells. Moreover, lineage tracing via an Oct4-CreER labeling system demonstrated that virtually all iNSC colonies originate from cells transiently expressing Oct4, whereas ablation of Oct4-positive cells prevented iNSC formation. Lastly, use of an alternative transdifferentiation cocktail that lacks OCT4 and was reportedly unable to support induced pluripotency, yielded iPSCs and iNSCs carrying the Oct4-CreER-derived lineage label. Together, these data suggest that iNSC generation using OKSM and related reprogramming factors requires passage through a transient iPSC state. 5 samples were anlyzed in total, 2 induced pluripotent stem cells (iPSCs), 1 neural stem cells (NSCs) and 2 induced NSCs (iNSCs)