Project description:The production of alternative RNA variants contributes to the tissue-specific regulation of gene expression. In the animal nervous system, a shift towards more distal 3’ processing sites generates hundreds of substantially extended messenger RNAs. These neuronal transcript signatures are crucial for nervous system development and function. However, no clear understanding of the mechanism of systematic 3’ extension in neurons has yet been achieved. Here, we report that the highly conserved RNA-binding protein ELAV globally regulates all events of neuronal 3’ end processing by directly binding to the proximal 3’ end of its target RNAs. We uncover an endogenous strategy of functional gene rescue, by which neuronal RNA signatures are safeguarded in a loss-of-function context. When not directly repressed by ELAV, the transcript encoding the ELAV paralogue FNE acquires a mini‑exon, which equips the new FNE protein with the ability to translocate to the nucleus and rescue neuronal 3’ end processing. We propose that exon-activated functional rescue is a widespread mechanism that ensures robustness of processes that are regulated by a hierarchy, rather than by redundancy, of effectors.

Project description:ELAV/Hu factors are conserved RNA binding proteins that play diverse roles in mRNA processing and regulation. The founding member, Drosophila Elav, was recognized as a vital neural factor 35 years ago. Nevertheless, still little is known about its impacts on the transcriptome, and potential functional overlap with its paralogs. Building on our recent findings that neural-specific lengthened 3' UTR isoforms are co-determined by ELAV/Hu factors, we address their impacts on splicing. While only a few splicing targets of Drosophila are known, we find that ectopic expression of the three family members (Elav, Fne and Rbp9) induces overlapping changes to hundreds of cassette exon and dozens of alternative last exon (ALE) splicing events. Reciprocally, double mutants of elav/fne, but not elav alone, have opposite effects on both classes of regulated mRNA processing events in the larval CNS. While manipulation of Drosophila ELAV/Hu factors induces both exon skipping and inclusion, motif analysis indicates their major direct effects are to suppress cassette exon usage. Moreover, the roles of ELAV/HU factors in global promotion of distal ALE splicing are mechanistically linked to terminal 3' UTR extensions in neurons, since both involve local suppression of proximal polyadenylation signals via ELAV/Hu binding sites downstream of cleavage sites. The phenotypic impact of combined ELAV/Hu activities in neural mRNA processing is overt, since fne loss strongly enhances neuronal differentiation phenotypes in elav mutants. Finally, we provide evidence for conservation in mammalian neurons, which undergo broad programs of distal ALE and APA lengthening, linked to ELAV/Hu motifs downstream of regulated polyadenylation sites. Overall, ELAV/Hu proteins orchestrate multiple conserved programs of neuronal mRNA processing by suppressing alternative exons and polyadenylation sites.

Project description:The goals of this study are to establish a cell line based analysis platform to unbiasedly evaluate the capabilities of Elav/Hu family RNA binding proteins in regulating neural specific 3' UTR extension; and perform quantitative analysis of global 3' UTR extension regulated by individual Elav/Hu family RNA binding protein. We reported that in non-neural tissue context such as S2R+ cells, with the overexpression of wildtype Elav, Rbp9 and Fne, we observed global 3' UTR extensions for hundreds of genes, whose 3' UTR extension corespond with those detected in head; also, RNA rocognition motif mutant versions of Elav, Rbp9 and Fne loss the ability to regulate the generation of neural specific 3' UTR extension. We reported here for the first time, we show quantitative comparison between Elav/Hu family RNA binding proteins in regulating neural specific 3' UTR landscape and imply the overlapping activities of Elav/Hu family RNA binding proteins specifying neural 3' UTR landscape in Drosophila.

Project description:RNA-binding proteins play important roles in neuronal development and function. We sought to understand the role of the RNA-binding protein Found in neurons (Fne) in regulating the development of Drosophila larval class IV dendritic arborization neurons, in part by identifying its transcript targets using TRIBE. We were able to identify many cell adhesion proteins and cytoskeletal regulators as targets of Fne, which is consistent with our genetic and phenotypic analysis of the role of Fne in class IV da neurons.

Project description:Alternative polyadenylation (APA) has been implicated in a variety of developmental and disease processes, such as stem cell differentiation and cancer. A particularly dramatic form of APA has been documented in the developing nervous system of flies and mammals, whereby a variety of neurogenic genes undergo coordinate extension of their 3’ UTRs. In Drosophila, the RNA-binding protein ELAV inhibits RNA processing at proximal polyadenylation (poly(A)) sites, thereby fostering the formation of 3’ extensions that can reach 12 kb in length. Here, we present evidence that paused Pol II plays an important role in the selective recruitment of ELAV to elongated genes. Replacing native promoters of elongated genes with heterologous promoters blocks normal 3’ extension in the nervous system, while native promoters can induce 3’ extension in ectopic tissues expressing ELAV. Computational analyses suggest that the promoter regions of elongated genes tend to contain paused Pol II and associated cis-regulatory elements such as GAGA. ELAV ChIP-Seq assays indicate pervasive binding to the promoter regions of extended genes. Our study provides the first evidence for a regulatory link between promoter-proximal pausing and APA. ELAV ChIP-Seq assays were conducted with nuclei obtained from 6-8 hr and 10-12 hr embryos

Project description:The recognition of synaptic partners and specification of synaptic properties are fundamental for the function of neuronal circuits. 'Terminal selector' transcription factors coordinate the expression of terminal gene batteries that specify cell type-specific properties. Moreover, pan-neuronal alternative splicing regulators have been implicated in directing neuronal differentiation. However, the cellular logic of how splicing regulators instruct specific synaptic properties remains poorly understood. Here, we combine genome-wide mapping of mRNA targets and cell type-specific loss-of-function studies to uncover the contribution of the nuclear RNA binding protein SLM2 to hippocampal synapse specification. We find that SLM2 preferentially binds and regulates alternative splicing of transcripts encoding synaptic proteins, thereby generating cell type-specific isoforms. In the absence of SLM2, cell type-specification, differentiation, and viability are unaltered and neuronal populations exhibit normal intrinsic properties. By contrast, cell type-specific loss of SLM2 results in highly selective, non-cell autonomous synaptic phenotypes, altered synaptic transmission, and associated defects in a hippocampus-dependent memory task. Thus, alternative splicing provides a critical layer of gene regulation that instructs specification of neuronal connectivity in a trans-synaptic manner.  

Project description:Alternative polyadenylation is a widespread mechanism involving about half of the expressed genes, resulting in varying lengths of the 3' UTR and changes of the post-transcriptional processing, localization, miRNA targeting and stability of mRNAs. During neuronal differentiation a variety of mRNAs change the length of their 3' UTR, promoting the longer version of the transcripts. Little is known about polyA+ site usage during differentiation of mammalian neural progenitors. Here we exploit a model of adherent neural stem (ANS) cells, which homogeneously and efficiently differentiate into GABAergic neurons. RNAseq data shows a global trend towards lengthening of the 3’ UTRs during differentiation. Enriched expression of the long 3’ UTR variants of Pes1 and Gng2 was detected in areas of cortical and subcortical neuronal differentiation, respectively, in the mouse brain by two-probes FISH analyses. In Drosophila the choice of polyA+ site has been shown to be regulated by the RNA-binding protein Elav, which inhibits polyadenylation at proximal sites while interacting with paused Pol-II promoters. Among the coding genes upregulated during differentiation of ANS cells we found Elavl3, a neural-specific RNA-binding protein homologous to Drosophila Elav. The silencing of Elavl3 in ANS cells resulted in impaired elongation of the 3’UTR length and delayed neuronal differentiation. These results indicate that choice of the polyA+ site and lengthening of 3’ UTRs is a possible additional mechanism of posttranscriptional RNA modification involved in neuronal differentiation.

Project description:PTBP1 and PTBP2 control alternative splicing programs during neuronal development, but the cellular functions of most PTBP1/2-regulated isoforms remain unknown. We show that PTBP1 guides developmental gene expression by regulating the transcription factor Pbx1. We identify exons that are differentially spliced when mouse embryonic stem cells (ESCs) differentiate into neuronal progenitor cells (NPCs) and neurons, and transition from PTBP1 to PTBP2 expression. We define those exons controlled by PTBP1 in ESCs and NPCs by RNA-seq analysis after PTBP1 depletion and PTBP1 crosslinking-immunoprecipitation. We find that PTBP1 represses Pbx1 exon 7 and the expression of its neuronal isoform Pbx1a in ESC. Using CRISPR-Cas9 to delete regulatory elements for exon 7, we induce Pbx1a expression in ESCs, finding that this activates transcription of specific neuronal genes including known Pbx1 targets. Thus PTBP1 controls the activity of Pbx1 and suppresses its neuronal transcriptional program prior to differentiation. HB9-GFP mESCs were differentiated into mNPCs and mMNs. Poly-A RNA was isolated from isolated populations of mESCs, mNPCs, and mMNs for RNA-sequencing and splicing analyses.

Project description:PTBP1 and PTBP2 control alternative splicing programs during neuronal development, but the cellular functions of most PTBP1/2-regulated isoforms remain unknown. We show that PTBP1 guides developmental gene expression by regulating the transcription factor Pbx1. We identify exons that are differentially spliced when mouse embryonic stem cells (ESCs) differentiate into neuronal progenitor cells (NPCs) and neurons, and transition from PTBP1 to PTBP2 expression. We define those exons controlled by PTBP1 in ESCs and NPCs by RNA-seq analysis after PTBP1 depletion and PTBP1 crosslinking-immunoprecipitation. We find that PTBP1 represses Pbx1 exon 7 and the expression of its neuronal isoform Pbx1a in ESC. Using CRISPR-Cas9 to delete regulatory elements for exon 7, we induce Pbx1a expression in ESCs, finding that this activates transcription of specific neuronal genes including known Pbx1 targets. Thus PTBP1 controls the activity of Pbx1 and suppresses its neuronal transcriptional program prior to differentiation. 46C mESCs and mNPCs were cross-linked at 100 mJ/cm2. Cell pellets were collected and flash-frozen for iCLIP library preparation. Libraries were subjected to 100 single-end RNA-sequencing.

Project description:SAGA is a highly conserved transcriptional co-activator complex involved in multiple steps of transcription with activities that function both pre and post initiation. Loss of individual subunits results in developmental defects, suggesting a role in development. To better understand the roles of SAGA functions in developmental gene expression and it's relationship with RNA polymerase II, we examined its composition, binding profile, and the effects of subunit loss on gene expression in two distinct cell types in late stage Drosophila embryos: muscle and neurons. Chromatin IP of FLAG-tagged SAGA subunit Ada2b, and RNA polymerase II (antibody 4H8), was performed in neuronal (elav+) or muscle (mef2+) cells isolated by FACS from late stage embryos, and compared to whole cell extracts (input). The control constists of an IP performed in neuronal cells from a non-tagged strain.