Mechanisms and Regulation of Alternative Pre-mRNA Splicing

Lee, Yeon; Rio, Donald C.

doi:10.1146/annurev-biochem-060614-034316

Cited by 1,010 publications

(981 citation statements)

References 260 publications

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“…The reconstruction resulted in a set of 6,541 MXE candidates in 1,542 protein‐coding genes, including 1,058 (68.6%) genes for which we predicted 1,722 completely novel exons in previously intronic regions (Fig 1B). Most introns in human genes are extremely long necessitating careful and strict validation of the MXE candidates to exclude false‐positive predictions (Lee & Rio, 2015). …”

Section: Resultsmentioning

confidence: 99%

“…Surprisingly, the majority of the annotated MXEs are of this type (91 of 122; 75%) as well as many exons previously annotated as other splice types (44 of 662), but only few of the novel MXEs predicted in intronic regions (25 of 615; Appendix Fig S3A and D). These numbers suggest that splicing of the remaining 484 MXE clusters is tightly regulated by other mechanisms (Fig 2B) such as RNA–protein interactions, interactions between small nuclear ribonucleoproteins and splicing factors (Lee & Rio, 2015), and competitive RNA secondary structural elements (Graveley, 2005; Yang et al , 2012; Lee & Rio, 2015). Competing RNA secondary structures are, however, usually not conserved across long evolutionary distances.…”

Section: Resultsmentioning

confidence: 99%

“…Alternative splicing of pre‐messenger RNAs is a mechanism common to almost all eukaryotes to generate a plethora of protein variants out of a limited number of genes (Matlin et al , 2005; Nilsen & Graveley, 2010; Lee & Rio, 2015). High‐throughput studies suggested that not only 95–100% of all multi‐exon genes in human are affected (Pan et al , 2008; Wang et al , 2008; Gerstein et al , 2014) but also that alternative splicing patterns strongly diverged between vertebrate lineages implying a pronounced role in the evolution of phenotypic complexity (Barbosa‐Morais et al , 2012; Merkin et al , 2012).…”

Section: Introductionmentioning

confidence: 99%

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The landscape of human mutually exclusive splicing

Hatje

Rahman

Vidal

et al. 2017

Molecular Systems Biology

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Mutually exclusive splicing of exons is a mechanism of functional gene and protein diversification with pivotal roles in organismal development and diseases such as Timothy syndrome, cardiomyopathy and cancer in humans. In order to obtain a first genomewide estimate of the extent and biological role of mutually exclusive splicing in humans, we predicted and subsequently validated mutually exclusive exons (MXEs) using 515 publically available RNA‐Seq datasets. Here, we provide evidence for the expression of over 855 MXEs, 42% of which represent novel exons, increasing the annotated human mutually exclusive exome more than fivefold. The data provide strong evidence for the existence of large and multi‐cluster MXEs in higher vertebrates and offer new insights into MXE evolution. More than 82% of the MXE clusters are conserved in mammals, and five clusters have homologous clusters in Drosophila. Finally, MXEs are significantly enriched in pathogenic mutations and their spatio‐temporal expression might predict human disease pathology.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The landscape of human mutually exclusive splicing

Hatje

Rahman

Vidal

et al. 2017

Molecular Systems Biology

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“…The exclusion or inclusion of alternative exons highly depends on the position and context of splicing cis ‐regulatory sequences within alternative exons or the flanking introns, including exonic splicing enhancers or silencers (ESEs or ESSs) and intronic splicing enhancers or silencers (ISEs or ISSs) that recruit splicing regulators 16, 17. Using the RIP approach, we observed that both mature Itgb1D mRNA and Itgb1 pre‐mRNA, which share the 81‐bp AED sequence, were detected in LRP6 protein‐immunoprecipitated transcripts (Figure 3A), implicating that the AED was the potential cis ‐regulatory element.…”

Section: Resultsmentioning

confidence: 99%

“…Regulation of this process is highly complicated, depending on loosely defined cis ‐acting regulatory sequence elements, trans‐acting protein factors and cellular responses to varying environmental conditions. Deciphering the splicing code requires understanding of splicing regulatory RNA‐binding proteins (RBPs) and their cis‐acting binding sites 16. There are virtually no data on the sequence preferences of RBPs in most organisms.…”

Section: Discussionmentioning

confidence: 99%

Low‐density lipoprotein receptor‐related protein 6 regulates alternative pre‐mRNA splicing

Yuan

Wang

et al. 2018

J Cellular Molecular Medi

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Low‐density lipoprotein receptor‐related protein 6 (LRP6) serves as a Wnt coreceptor. Although Wnt/LRP6 signalling is best known for the β‐catenin‐dependent regulation of target genes in tissue development and homeostasis, emerging evidence demonstrates the biological aspects of LRP6 beyond a Wnt coreceptor. Whether LRP6 modulates tissue development in a Wnt/β‐catenin signalling‐independent manner remains unknown. Using a model of striated muscle development, we observed that LRP6 was almost undetectable in proliferating myoblasts, whereas its expression gradually increased in the nucleus of myodifferentiating cells. During myodifferentiation, LRP6 modulated the muscle‐specific splicing of integrin‐β1D and consequent myotube maturation independently of the β‐catenin‐dependent Wnt signalling. Furthermore, we identified that the carboxy‐terminal serine‐rich region in LRP6 bond to the adenine‐rich sequence within alternative exon D (AED) of integrin‐β1 pre‐mRNA, and therefore, elicited AED inclusion when the spliceosome was recruited to the splice site. The interaction of LRP6 with the adenine‐rich sequence was sufficient to overcome AED exclusion by a splicing repressor, polypyrimidine tract binding protein‐1. Besides the integrin‐β1, deep RNA sequencing in different types of cells revealed that the LRP6‐mediated splicing regulation was widespread. Thus, our findings implicate LRP6 as a potential regulator for alternative pre‐mRNA splicing.

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Global analysis of RNA–protein interactions in TNF‐α induced alternative splicing in metabolic disorders

et al. 2021

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In this report, using the database of RNA-binding protein specificities (RBPDB) and our previously published RNA-seq data, we analyzed the interactions between RNA and RNA-binding proteins to decipher the role of alternative splicing in metabolic disorders induced by TNF-a. We identified 13 395 unique RNA-RBP interactions, including 385 unique RNA motifs and 35 RBPs, some of which (including MBNL-1 and 3, ZFP36, ZRANB2, and SNRPA) are transcriptionally regulated by TNF-a. In addition to some previously reported RBPs, such as RBMX and HuR/ELAVL1, we found a few novel RBPs, such as ZRANB2 and SNRPA, to be involved in the regulation of metabolic syndrome-associated genes that contain an enrichment of tetrameric RNA sequences (AUUU). Taken together, this study paves the way for novel RNA-protein interaction-based therapeutics for treating metabolic syndromes.

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Mechanisms and Regulation of Alternative Pre-mRNA Splicing

Cited by 1,010 publications

References 260 publications

The landscape of human mutually exclusive splicing

The landscape of human mutually exclusive splicing

Low‐density lipoprotein receptor‐related protein 6 regulates alternative pre‐mRNA splicing

Global analysis of RNA–protein interactions in TNF‐α induced alternative splicing in metabolic disorders

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