Alternative splicing and disease

Tazi, Jamal; Bakkour, Nadia; Stamm, Stefan

doi:10.1016/j.bbadis.2008.09.017

Cited by 484 publications

(385 citation statements)

References 183 publications

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“…This is an essential regulatory process. Many splicing factors display embryonic lethality when knocked out, and genomic aberrations that alter splicing are associated with a plethora of diseases (Tazi et al 2009). In transcript model reconstructions, e.g., using Cufflinks, Trinity, or StringTie (Trapnell et al 2010;Grabherr et al 2011;Pertea et al 2015), isoform reconstruction is driven by sequence reads that cross exon-exon splicing junctions.…”

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confidence: 99%

Improved definition of the mouse transcriptome via targeted RNA sequencing

et al. 2016

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Targeted RNA sequencing (CaptureSeq) uses oligonucleotide probes to capture RNAs for sequencing, providing enriched read coverage, accurate measurement of gene expression, and quantitative expression data. We applied CaptureSeq to refine transcript annotations in the current murine GRCm38 assembly. More than 23,000 regions corresponding to putative or annotated long noncoding RNAs (lncRNAs) and 154,281 known splicing junction sites were selected for targeted sequencing across five mouse tissues and three brain subregions. The results illustrate that the mouse transcriptome is considerably more complex than previously thought. We assemble more complete transcript isoforms than GENCODE, expand transcript boundaries, and connect interspersed islands of mapped reads. We describe a novel filtering pipeline that identifies previously unannotated but high-quality transcript isoforms. In this set, 911 GENCODE neighboring genes are condensed into 400 expanded gene models. Additionally, 594 GENCODE lncRNAs acquire an open reading frame (ORF) when their structure is extended with CaptureSeq. Finally, we validate our observations using current FANTOM and Mouse ENCODE resources.

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confidence: 99%

Improved definition of the mouse transcriptome via targeted RNA sequencing

et al. 2016

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“…2,3 Indeed, the large majority of multi-exon human genes undergo alternative splicing (AS) to produce at least two mRNA variants. 4,5 As regulation of AS profoundly influences physiological and pathological processes, 3,6 the full comprehension of the molecular mechanisms regulating this step of pre-mRNA processing is of fundamental importance.Splicing is physically and functionally coupled to transcription. 7-10 Two models have been proposed for how transcription might affect changes in AS patterns.…”

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confidence: 99%

The transcriptional co-activator SND1 is a novel regulator of alternative splicing in prostate cancer cells

et al. 2013

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Splicing abnormalities have profound impact in human cancer. Several splicing factors, including SAM68, have pro-oncogenic functions, and their increased expression often correlates with human cancer development and progression. Herein, we have identified using mass spectrometry proteins that interact with endogenous SAM68 in prostate cancer (PCa) cells. Among other interesting proteins, we have characterized the interaction of SAM68 with SND1, a transcriptional co-activator that binds spliceosome components, thus coupling transcription and splicing. We found that both SAM68 and SND1 are upregulated in PCa cells with respect to benign prostate cells. Upregulation of SND1 exerts a synergic effect with SAM68 on exon v5 inclusion in the CD44 mRNA. The effect of SND1 on CD44 splicing required SAM68, as it was compromised after knockdown of this protein or mutation of the SAM68-binding sites in the CD44 pre-mRNA. More generally, we found that SND1 promotes the inclusion of CD44 variable exons by recruiting SAM68 and spliceosomal components on CD44 pre-mRNA. Inclusion of the variable exons in CD44 correlates with increased proliferation, motility and invasiveness of cancer cells. Strikingly, we found that knockdown of SND1, or SAM68, reduced proliferation and migration of PCa cells. Thus, our findings strongly suggest that SND1 is a novel regulator of alternative splicing that promotes PCa cell growth and survival.Oncogene advance online publication, 2 September 2013; doi:10.1038/onc.2013.360Keywords: alternative splicing; SND1; SAM68; CD44; prostate cancer INTRODUCTION Nuclear processing of pre-mRNAs requires tightly regulated steps that ultimately yield a mature and functional mRNA. Splicing is the step that insures the removal of long non-coding sequences (introns) from the pre-mRNA and the joining of the exons. This phenomenon is driven by a large macromolecular complex, the spliceosome, composed of five small nuclear ribonucleoproteins (snRNPs) and over 200 auxiliary proteins. 1 In higher eukaryotes, a large number of exons can be alternatively spliced to yield different transcripts from a single gene, thereby increasing the coding potential of the genome. 2,3 Indeed, the large majority of multi-exon human genes undergo alternative splicing (AS) to produce at least two mRNA variants. 4,5 As regulation of AS profoundly influences physiological and pathological processes, 3,6 the full comprehension of the molecular mechanisms regulating this step of pre-mRNA processing is of fundamental importance.Splicing is physically and functionally coupled to transcription. 7-10 Two models have been proposed for how transcription might affect changes in AS patterns. The 'recruitment model' suggests that the transcription apparatus physically interacts with splicing regulators, thereby affecting splicing decisions. The C-terminal domain (CTD) of the largest subunit of the RNA polymerase II (RNAPII) has a central role in this coupling process by favoring the recruitment of RNA processing factors on the nascent transcripts. 9,10 ...

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“…The accumulation of disease-related mutations in the spliceosome, the machinery for intron recognition and removal, correlates with aberrations in alternative splicing that have been suggested to contribute to tumorigenesis (Tazi et al 2009;Zhang and Manley 2013;Sveen et al 2016). Disease-related mutations cluster in proteins involved in spliceosome assembly, particularly ones important for intron recognition, such as SF3B1 (also known as SAP155, SF3b155, and Hsh155p), SRSF1, and U2AF (Yoshida et al 2011;Quesada et al 2012).…”

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SF3B1/Hsh155 HEAT motif mutations affect interaction with the spliceosomal ATPase Prp5, resulting in altered branch site selectivity in pre-mRNA splicing

et al. 2016

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Mutations in the U2 snRNP component SF3B1 are prominent in myelodysplastic syndromes (MDSs) and other cancers and have been shown recently to alter branch site (BS) or 3 ′ splice site selection in splicing. However, the molecular mechanism of altered splicing is not known. We show here that hsh155 mutant alleles in Saccharomyces cerevisiae, counterparts of SF3B1 mutations frequently found in cancers, specifically change splicing of suboptimal BS pre-mRNA substrates. We found that Hsh155p interacts directly with Prp5p, the first ATPase that acts during spliceosome assembly, and localized the interacting regions to HEAT (Huntingtin, EF3, PP2A, and TOR1) motifs in SF3B1 associated with disease mutations. Furthermore, we show that mutations in these motifs from both human disease and yeast genetic screens alter the physical interaction with Prp5p, alter branch region specification, and phenocopy mutations in Prp5p. These and other data demonstrate that mutations in Hsh155p and Prp5p alter splicing because they change the direct physical interaction between Hsh155p and Prp5p. This altered physical interaction results in altered loading (i.e., "fidelity") of the BS-U2 duplex into the SF3B complex during prespliceosome formation. These results provide a mechanistic framework to explain the consequences of intron recognition and splicing of SF3B1 mutations found in disease.

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Alternative splicing and disease

Cited by 484 publications

References 183 publications

Improved definition of the mouse transcriptome via targeted RNA sequencing

Improved definition of the mouse transcriptome via targeted RNA sequencing

The transcriptional co-activator SND1 is a novel regulator of alternative splicing in prostate cancer cells

SF3B1/Hsh155 HEAT motif mutations affect interaction with the spliceosomal ATPase Prp5, resulting in altered branch site selectivity in pre-mRNA splicing

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