Regulation of alternative splicing by PTB and associated factors

Spellman, Rachel; Rideau, Alexis; Matlin, Arianne J.; Gooding, Clare; Robinson, Fiona; McGlincy, Nicholas J.; Grellscheid, Sushma Nagaraja; Southby, Justine; Wollerton, Matthew; Smith, Chris

doi:10.1042/bst0330457

Cited by 118 publications

(110 citation statements)

References 29 publications

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“…3A, upper panel); this resulted in greater than 90% depletion of hUpf1 protein by 72 h posttransfection. A splice variant of the polypyrimidine transcript binding protein (PTB), known to be a target of NMD (48), was used as a positive control for NMD inhibition (Fig. 3A, left panel).…”

Section: Resultsmentioning

confidence: 99%

“…After 18 h, 25 to 100 nM small interfering RNA (siRNA; siGENOME SMARTpool reagent; Dharmacon) was mixed with Oligofectamine reagent (Invitrogen), incubated at room temperature for 20 min, and added drop-wise to cells. At 48,72, and 96 h post-siRNA transfection, cells were harvested for either whole-cell lysates or RNA isolation. The concentration and time required for optimal downregulation were determined empirically by both RT-PCR and Western blot analysis.…”

Section: Methodsmentioning

confidence: 99%

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Caffeine Regulates Alternative Splicing in a Subset of Cancer-Associated Genes: a Role for SC35

Shi

Pabon

et al. 2008

Molecular and Cellular Biology

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Alternative splicing of pre-mRNA contributes significantly to human proteomic complexity, playing a key role in development, gene expression and, when aberrant, human disease onset. Many of the factors involved in alternative splicing have been identified, but little is known about their regulation. Here we report that caffeine regulates alternative splicing of a subset of cancer-associated genes, including the tumor suppressor KLF6. This regulation is at the level of splice site selection, occurs rapidly and reversibly, and is concentration dependent. We have recapitulated caffeine-induced alternative splicing of KLF6 using a cell-based minigene assay and identified a "caffeine response element" within the KLF6 intronic sequence. Significantly, a chimeric minigene splicing assay demonstrated that this caffeine response element is functional in a heterologous context; similar elements exist within close proximity to caffeine-regulated exons of other genes in the subset. Furthermore, the SR splicing factor, SC35, was shown to be required for induction of the alternatively spliced KLF6 transcript. Importantly, SC35 is markedly induced by caffeine, and overexpression of SC35 is sufficient to mimic the effect of caffeine on KLF6 alternative splicing. Taken together, our data implicate SC35 as a key player in caffeine-mediated splicing regulation. This novel effect of caffeine provides a valuable tool for dissecting the regulation of alternative splicing of a large gene subset and may have implications with respect to splice variants associated with disease states.Alternative splicing of pre-mRNA is an essential process by which eukaryotes generate functionally diverse isoforms from a single gene through the selective joining of different exons. This process responds to developmental and environmental cues, contributing substantially to cell-specific and tissue-specific gene expression; it is estimated that over 60% of human genes are alternatively spliced (36). Given the pervasive and profound involvement of alternative splicing in multiple cellular processes, it is clear that the choice of splice site can have major phenotypic consequences, and defects in the splicing pathway are associated with a variety of disease states. Indeed, as many as 50% of human genetic diseases arise from mutations affecting splicing choices (32). For example, it has recently been demonstrated that many cancer-associated genes are regulated by alternative splicing and that a number of splice variants appear to be unique to the malignant state (53, 57). Whether these splice variants play a role in carcinogenesis or tumor maintenance remains to be determined, but their consistent association with the malignant state suggests, at the very least, a clear value as diagnostic indicators and a potential as therapeutic targets (8,22). Therefore, a better understanding of the etiology of these cancer splice variants has become an imperative.Decades of elegant studies have defined the basic splicing mechanism, which requires the interaction of spl...

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Caffeine Regulates Alternative Splicing in a Subset of Cancer-Associated Genes: a Role for SC35

Shi

Pabon

et al. 2008

Molecular and Cellular Biology

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“…67 Consequently, when PTB levels are high, PTB production is slowed by targeting PTB transcripts for NMD and when PTB levels are low, production is accelerated by reducing the proportion of transcripts that are degraded. 67,69,70 A similar autoregulatory process has been reported for members of a family of splicing factors known as SR proteins. Overexpression of the SR protein SC35 upregulates the splicing of its own NMD-targeted isoform to reduce protein production.…”

Section: Autoregulatory Unproductive Splicingmentioning

confidence: 97%

The Coupling of Alternative Splicing and Nonsense-Mediated mRNA Decay

Lareau¹,

Brooks²,

Soergel³

et al. 2007

Advances in Experimental Medicine and Biology

205

192

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M ost human genes exhibit alternative splicing, but not all alternatively spliced transcripts produce functional proteins. Computational and experimental results indicate that a substantial fraction of alternative splicing events in humans result in mRNA isoforms that harbor a premature termination codon (PTC). These transcripts are predicted to be degraded by the nonsense-mediated mRNA decay (NMD) pathway. One explanation for the abundance of PTC-containing isoforms is that they represent splicing errors that are identified and degraded by the NMD pathway. Another potential explanation for this startling observation is that cells may link alternative splicing and NMD to regulate the abundance of mRNA transcripts. This mechanism, which we call "Regulated Unproductive Splicing and Translation" (RUST), has been experimentally shown to regulate expression of a wide variety of genes in many organisms from yeast to human. It is frequently employed for autoregulation of proteins that affect the splicing process itself. Thus, alternative splicing and NMD act together to play an important role in regulating gene expression.

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“…Instead, we discovered that 9G8 exerts its effect by binding to the intronic splicing silencer defined by deletion Δ11/18 and by a bevy of FTDP mutations (M11, 12, 13, 14, 16). This is unusual: in the traditional division of labor, SR proteins act on exonic elements whereas hnRNP and CELF proteins act on intronic elements (Sanford et al, 2005;Spellman et al, 2005). However, SR proteins also act as bridging elements for regulated exons (Sanford et al, 2005) and 9G8 may be fulfilling that role in this instance.…”

Section: G8 Inhibits Inclusion Of Tau Exon 10 By Binding To the Intrmentioning

confidence: 99%

SR protein 9G8 modulates splicing of tau exon 10 via its proximal downstream intron, a clustering region for frontotemporal dementia mutations

Gao

Wang

et al. 2007

Molecular and Cellular Neuroscience

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The microtubule-associated protein tau is important to normal neuronal function in the mammalian nervous system. Aggregated tau is the major component of neurofibrillary tangles (NFTs), present in several neurodegenerative diseases, including Alzheimer's and frontotemporal dementia with Parkinsonism (FTDP). Splicing misregulation of adult-specific exon 10 results in expression of abnormal ratios of tau isoforms, leading to FTDP. Positions +3 to +16 of the intron downstream of exon 10 define a clustering region for point mutations that are found in FTDP. The serine/argininerich (SR) factor 9G8 strongly inhibits inclusion of tau exon 10. In this study, we established that 9G8 binds directly to this clustering region, requires a wild-type residue at position +14 to inhibit exon inclusion, and RNAi constructs against 9G8 increase exon 10 inclusion. These results indicate that 9G8 plays a key role in regulation of exon 10 splicing and imply a pathogenic role in neurodegenerative diseases.

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Regulation of alternative splicing by PTB and associated factors

Cited by 118 publications

References 29 publications

Caffeine Regulates Alternative Splicing in a Subset of Cancer-Associated Genes: a Role for SC35

Caffeine Regulates Alternative Splicing in a Subset of Cancer-Associated Genes: a Role for SC35

The Coupling of Alternative Splicing and Nonsense-Mediated mRNA Decay

SR protein 9G8 modulates splicing of tau exon 10 via its proximal downstream intron, a clustering region for frontotemporal dementia mutations

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