HITS-CLIP and Integrative Modeling Define the Rbfox Splicing-Regulatory Network Linked to Brain Development and Autism

Weyn-Vanhentenryck, Sebastien M.; Mele, Aldo; Yan, Qinghong; Sun, Shuying; Farny, Natalie G.; Zuo, Zhuang; Xue, Chenghai; Herre, Margaret; Silver, Pamela A.; Zhang, Michael Q.; Krainer, Adrian R.; Darnell, Robert B.; Zhang, Chaolin

doi:10.1016/j.celrep.2014.02.005

Cited by 320 publications

(456 citation statements)

References 53 publications

(119 reference statements)

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“…The similar phenotype observed for Rbfox1 and Rbfox2 KD suggests that both RBPs regulate overlapping sets of transcripts in beta cells. This is in agreement with previous studies showing that Rbfox proteins bind to the same UGCAUG motif due to the presence of a common RNA binding domain (28,32,62). Functional analysis of the role of Rbfox proteins in beta cells (present data) indicates that Rbfox depletion increases the insulin secretory capacity by affecting actin depolymerization kinetics following glucose stimulation.…”

Section: Role Of Neuron-enriched Rna-binding Proteins In Beta Cellssupporting

confidence: 82%

“…Gelsolin enhances insulin secretion by mediating glucose-dependent actin cytoskeleton remodeling and by interacting with t-SNARE proteins, thus favoring insulin granule exocytosis (29,30). In line with the present findings, Rbfox1 targets in brain and muscle are enriched in genes involved in cytoskeleton organization and actin filament-based processes (28,57). We cannot exclude, however, that other Rbfox targets (such as calcium channels) also contribute to the observed phenotype.…”

Section: Role Of Neuron-enriched Rna-binding Proteins In Beta Cellssupporting

confidence: 78%

“…Our data analysis identified a cluster of RBPs that are expressed in both brain and in human islets. This cluster includes members of the Elavl, Nova, and Rbfox families, which have been implicated in neuronal physiology and disease (28,(31)(32)(33)(34)(35). We found that Elavl4 and Nova2 are required for beta cell survival, and their depletion leads to activation of the intrinsic pathway of apoptosis.…”

Section: Discussionmentioning

confidence: 85%

“…Rbfox1 Regulates Alternative Splicing of Key Genes Controlling Insulin Secretion-To identify Rbfox target genes that might affect insulin release, we re-analyzed a previously published dataset that identified 1,059 Rbfox-regulated AS events in mouse brain (28). Pathway enrichment analysis using IPA (Ingenuity Systems) and DAVID (david.abcc.ncifcrf.gov) software showed that Rbfox-regulated transcripts in brain are enriched in pathways that can affect insulin secretion in beta cells, including cytoskeleton organization, vesicle-mediated transport, and calcium signaling.…”

Section: Role Of Neuron-enriched Rna-binding Proteins In Beta Cellsmentioning

confidence: 99%

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Neuron-enriched RNA-binding Proteins Regulate Pancreatic Beta Cell Function and Survival

Juan-Mateu

Rech

Villate

et al. 2017

Journal of Biological Chemistry

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Edited by Jeffrey E. PessinPancreatic beta cell failure is the central event leading to diabetes. Beta cells share many phenotypic traits with neurons, and proper beta cell function relies on the activation of several neuron-like transcription programs. Regulation of gene expression by alternative splicing plays a pivotal role in brain, where it affects neuronal development, function, and disease. The role of alternative splicing in beta cells remains unclear, but recent data indicate that splicing alterations modulated by both inflammation and susceptibility genes for diabetes contribute to beta cell dysfunction and death. Here we used RNA sequencing to compare the expression of splicing-regulatory RNA-binding proteins in human islets, brain, and other human tissues, and we identified a cluster of splicing regulators that are expressed in both beta cells and brain. Four of them, namely Elavl4, Nova2, Rbox1, and Rbfox2, were selected for subsequent functional studies in insulin-producing rat INS-1E, human EndoC-␤H1 cells, and in primary rat beta cells. Silencing of Elavl4 and Nova2 increased beta cell apoptosis, whereas silencing of Rbfox1 and Rbfox2 increased insulin content and secretion. Interestingly, Rbfox1 silencing modulates the splicing of the actin-remodeling protein gelsolin, increasing gelsolin expression and leading to faster glucose-induced actin depolymerization and increased insulin release. Taken together, these findings indicate that beta cells share common splicing regulators and programs with neurons. These splicing regulators play key roles in insulin release and beta cell survival, and their dysfunction may contribute to the loss of functional beta cell mass in diabetes.Insulin-secreting pancreatic beta cells share many phenotypic traits with neurons. Similarities range from an analogous physiology and function to similar development and gene expression (1). Beta cells release insulin using a similar exocytotic machinery as used by neurons to release neurotransmitters. Indeed, insulin is stored and secreted using scaffolding proteins and synaptic-like vesicles similar to neuronal cells (2-4), and like neurons, beta cells are able to generate action potentials in response to different stimuli (5). Despite having different embryonic origins (6, 7), global gene expression and active chromatin marks of beta cells are closer to neural tissues than to any other tissue, including other pancreatic cells (8). Neurons are phylogenetically older than beta cells, and in some primitive organisms neurons express insulin and regulate circulating glucose levels (9, 10). Taken together, these findings suggest that beta cells have evolved into specialized insulinsecretory cells by adopting, at least in part, neuronal transcription programs (1). Supporting this hypothesis, both neurons and beta cells lose the expression of the transcriptional repressor element-1 silencing transcription factor (REST) 5 during differentiation (11). REST is expressed in most non-neuronal cells and acts as a master negative regula...

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Section: Role Of Neuron-enriched Rna-binding Proteins In Beta Cellssupporting

confidence: 82%

Section: Role Of Neuron-enriched Rna-binding Proteins In Beta Cellssupporting

confidence: 78%

Section: Discussionmentioning

confidence: 85%

Section: Role Of Neuron-enriched Rna-binding Proteins In Beta Cellsmentioning

confidence: 99%

See 2 more Smart Citations

Neuron-enriched RNA-binding Proteins Regulate Pancreatic Beta Cell Function and Survival

Juan-Mateu

Rech

Villate

et al. 2017

Journal of Biological Chemistry

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“…S12). Rbfox and Nova are known to regulate AS of neuronal transcripts by activating or repressing exon inclusion depending on their binding position relative to the alternative exon (17,20,21). We found that both known and new cassette exons with neuron-specific inclusion 3B and SI Appendix, Fig.…”

Section: Extending the Mouse And Human Cortex Transcriptomes By Deepmentioning

confidence: 72%

Systematic discovery of regulated and conserved alternative exons in the mammalian brain reveals NMD modulating chromatin regulators

Yan

Weyn-Vanhentenryck

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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137

156

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Alternative splicing (AS) dramatically expands the complexity of the mammalian brain transcriptome, but its atlas remains incomplete. Here we performed deep mRNA sequencing of mouse cortex to discover and characterize alternative exons with potential functional significance. Our analysis expands the list of AS events over 10-fold compared with previous annotations, demonstrating that 72% of multiexon genes express multiple splice variants in this single tissue. To evaluate functionality of the newly discovered AS events, we conducted comprehensive analyses on central nervous system (CNS) cell type-specific splicing, targets of tissue-or cell typespecific RNA binding proteins (RBPs), evolutionary selection pressure, and coupling of AS with nonsense-mediated decay (AS-NMD). We show that newly discovered events account for 23-42% of all cassette exons under tissue-or cell type-specific regulation. Furthermore, over 7,000 cassette exons are under evolutionary selection for regulated AS in mammals, 70% of which are new. Among these are 3,058 highly conserved cassette exons, including 1,014 NMD exons that may function directly to control gene expression levels. These NMD exons are particularly enriched in RBPs including splicing factors and interestingly also regulators for other steps of RNA metabolism. Unexpectedly, a second group of NMD exons reside in genes encoding chromatin regulators. Although the conservation of NMD exons in RBPs frequently extends into lower vertebrates, NMD exons in chromatin regulators are introduced later into the mammalian lineage, implying the emergence of a novel mechanism coupling AS and epigenetics. Our results highlight previously uncharacterized complexity and evolution in the mammalian brain transcriptome.new alternative exon | brain transcriptome | RNA-Seq | nonsense-mediated decay | chromatin regulator M olecular diversity derived from alternative splicing (AS) is believed to be critical for the creation of different cell types and tissues with distinct physiological properties and functions (1). This is particularly relevant to the central nervous system (CNS), which requires a large protein repertoire to generate its intricate and complex neural circuits (2). Therefore, a comprehensive catalog of AS events and identification of those with potential functional significance are important steps toward understanding the complexity of the nervous system.Over the past two decades, discovery and characterization of AS events using different technologies have provided important insights into the evolution and regulation of AS (3, 4). Earlier expressed sequence tag (EST)-based studies revealed the prevalence of AS in mammals (5). Investigation of these AS events, especially comparison of AS patterns in different species, led to an important observation that AS is rapidly evolving in mammals, with many alternative exons created after the split of primates and rodents (6). Evolutionarily recent exons in general have low level of inclusion and frequently result in frame shift and premature...

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Identification of a classic nuclear localization signal at the N terminus that regulates the subcellular localization of Rbfox2 isoforms during differentiation of NMuMG and P19 cells

et al. 2016

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Edited by Claus AzzalinNuclear localization of the alternative splicing factor Rbfox2 is achieved by a C-terminal nuclear localization signal (NLS) which can be excluded from some Rbfox2 isoforms by alternative splicing. While this predicts nuclear and cytoplasmic localization, Rbfox2 is exclusively nuclear in some cell types. Here, we identify a second NLS in the N terminus of Rbfox2 isoform 1A that is not included in Rbfox2 isoform 1F. Rbfox2 1A isoforms lacking the Cterminal NLS are nuclear, whereas equivalent 1F isoforms are cytoplasmic. A shift in Rbfox2 expression toward cytoplasmic 1F isoforms occurs during epithelial to mesenchymal transition (EMT) and could be important in regulating the activity and function of Rbfox2.

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HITS-CLIP and Integrative Modeling Define the Rbfox Splicing-Regulatory Network Linked to Brain Development and Autism

Cited by 320 publications

References 53 publications

Neuron-enriched RNA-binding Proteins Regulate Pancreatic Beta Cell Function and Survival

Neuron-enriched RNA-binding Proteins Regulate Pancreatic Beta Cell Function and Survival

Systematic discovery of regulated and conserved alternative exons in the mammalian brain reveals NMD modulating chromatin regulators

Identification of a classic nuclear localization signal at the N terminus that regulates the subcellular localization of Rbfox2 isoforms during differentiation of NMuMG and P19 cells

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