Regulation of alternative 3' splice site selection by constitutive splicing factors.

We have devised an in vitro splicing assay in which the mutually exclusive exons 2 and 3 of alpha-tropomyosin act as competing 3' splice sites for joining to exon 1. Splicing in normal HeLa cell nuclear extracts results in almost exclusive joining of exons 1 and 3. Splicing in decreased nuclear extract concentrations and decreased ionic strength results in increased 1-2 splicing. We have used this assay to determine the role of three constitutive pre-mRNA splicing factors on alternative 3' splice site selection. Polypyrimidine tract binding protein (PTB) was found to inhibit the splicing of introns containing a strong binding site for this factor. However, the inhibitory effect of PTB could be partially reversed if pre-mRNAs were preincubated with U2 auxiliary factor (U2AF) prior to splicing in PTB-supplemented extracts. For alpha-tropomyosin, regulation of splicing by PTB and U2AF primarily affected the joining of exons 1-3 with no dramatic increases in 1-2 splicing being detected. Preincubation of pre-mRNAs with SR proteins led to small increases in 1-2 splicing. However, if pre-mRNAs were preincubated with SR proteins followed by splicing in PTB-supplemented extracts, there was a nearly complete reversal of the normal 1-2 to 1-3 splicing ratios. Thus, multiple pairwise, and sometimes antagonizing, interactions between constitutive pre-mRNA splicing factors and the pre-mRNA can regulate 3' splice site selection.     

Sex-specific alternative splicing of RNA from the transformer gene results from sequence-dependent splice site blockage

Sex-specific alternative splicing of RNA from the Drosophila transformer gene involves competition between two 3' splice sites. In the absence of Sex-lethal activity (as in males), only one site functions; in the presence of Sex-lethal activity (as in females), both sites function. Information for sex-specific splice site choice is contained within the intron itself. Deletions of the splice site used in males lead to Sex-lethal-independent use of the otherwise female-specific site. The relative amounts of unspliced and spliced RNA derived from these mutant genes do not change with changes in Sex-lethal activity. Specific nucleotide changes in the non-sex-specific splice site do not affect splicing activity but eliminate Sex-lethal-induced regulation. A deletion removing material between the two splice sites does not eliminate sex-specific regulation, while a deletion of the female splice site leads to a female-specific increase in unspliced RNA. These results are consistent with a model in which female-specific factors block the function of the non-sex-specific 3' splice site.     

Characterization of an alternative splicing by a NAGNAG splice acceptor site in the porcine KIT gene

The KIT gene has been shown to have multiple functions in hematopoiesis, melanogenesis, and gametogenesis. In addition, mutations of this gene cause pigmentation disorders in humans and mice and are responsible for coat color differences in pigs. While characterizing polymorphisms in the porcine KIT gene, we detected alternative splicing (AS) of the NAGNAG splice acceptor site at the boundary of intron 4 and exon 5. This AS event generated the E and I isoforms, characterized by insertion or deletion, respectively, of CAG at the borders of coding sequence. AS patterns measured in tissue samples from two randomly selected animals did not identified any tissue-specific outcomes. Analysis of AS patterns using three breeds demonstrated that Landrace and Large White pigs expressed both the E and I isoforms. In contrast, a subset of specimens from Korean Native Pigs (KNP) yielded a single I isoform. Alignment of the sequence from several species revealed that the region between the branch point sequence (BPS) and 3′ acceptor site is conserved. However, it is appeared that the selection of either the proximal or distal splice site varied between species. To test the breed specificity the NAGNAG splice acceptor site, we constructed two lineages of minigenes from KNP and Landrace pigs harboring breed-specific mutations. The minigene splicing assay demonstrated that both types of minigenes expressed both the E and I isoforms in two host cell lines, and no differences were detected in the AS pattern between the two breeds. We conclude that the AS at the NAGNAG splice acceptor site on intron 4/exon 5 in the porcine KIT gene is the result of noise selection at the splice site by the splicing machinery. Therefore, this AS event in the porcine KIT gene is unlikely to have any relationship with the coat color variations of Landrace and KNP breeds.     

Transcriptome analysis of alternative splicing events regulated by SRSF10 reveals position-dependent splicing modulation

Splicing factor SRSF10 is known to function as a sequence-specific splicing activator. Here, we used RNA-seq coupled with bioinformatics analysis to identify the extensive splicing network regulated by SRSF10 in chicken cells. We found that SRSF10 promoted both exon inclusion and exclusion. Motif analysis revealed that SRSF10 binding to cassette exons was associated with exon inclusion, whereas the binding of SRSF10 within downstream constitutive exons was associated with exon exclusion. This positional effect was further demonstrated by the mutagenesis of potential SRSF10 binding motifs in two minigene constructs. Functionally, many of SRSF10-verified alternative exons are linked to pathways of stress and apoptosis. Consistent with this observation, cells depleted of SRSF10 expression were far more susceptible to endoplasmic reticulum stress-induced apoptosis than control cells. Importantly, reconstituted SRSF10 in knockout cells recovered wild-type splicing patterns and considerably rescued the stress-related defects. Together, our results provide mechanistic insight into SRSF10-regulated alternative splicing events in vivo and demonstrate that SRSF10 plays a crucial role in cell survival under stress conditions.     

Sequestering of the 3' splice site in a theophylline-responsive riboswitch allows ligand-dependent control of alternative splicing

Despite the important role of alternative splicing in various aspects of biological processes, our ability to regulate this process at will remains a challenge. In this report, we asked whether a theophylline-responsive riboswitch could be adapted to manipulate alternative splicing. We constructed a pre-mRNA containing a single upstream 5' splice site and two 3' splice sites, of which the proximal 3' splice site is embedded in theophylline-responsive riboswitch. We show that this pre-mRNA spliced with preferential utilization of proximal 3' splice site in vitro. However, addition of theophylline to the splicing reaction promoted splicing at distal 3' splice site thereby changing the ratio of distal-to-proximal 3' splice site usage by more than twofold. Our data suggest that theophylline influenced 3' splice site choice without affecting the kinetics of the splicing reaction. We conclude that an in vitro selected riboswitch can be adapted to control alternative splicing, which may find many applications in basic, biotechnological, and biomedical research.     

Wobble splicing reveals the role of the branch point sequence-to-NAGNAG region in 3' tandem splice site selection

Alternative splicing involving the 3' tandem splice site NAGNAG sequence may play a role in the structure-function diversity of proteins. However, how 3' tandem splice site utilization is determined is not well understood. We previously demonstrated that 3' NAGNAG-based wobble splicing occurs mostly in a tissue- and developmental stage-independent manner. Bioinformatic analysis reveals that the nucleotide preceding the AG dinucleotide may influence 3' splice site utilization; this is also supported by an in vivo splicing assay. Moreover, we found that the intron sequence plays an important role in 3' splice site selection for NAGNAG wobble splicing. Mutations of the region between the branch site and the NAGNAG 3' splice site, indeed, affected the ratio of the distal/proximal AG selection. Finally, we found that single nucleotide polymorphisms around the NAGNAG motif could affect the splice site choice, which may lead to a change in mRNA patterns and influence protein function. We conclude that the NAGNAG motif and its upstream region to the branch point sequence are required for 3' tandem splice site selection.     

Modulation of survival motor neuron pre-mRNA splicing by inhibition of alternative 3' splice site pairing

Spinal muscular atrophy is caused by the loss of functional survival motor neuron (SMN1) alleles. A translationally silent nucleotide transition in the duplicated copy of the gene (SMN2) leads to exon 7 skipping and expression of a nonfunctional gene product. It has been suggested that differential SMN2 splicing is caused by the disruption of an exonic splicing enhancer. Here we show that the single nucleotide difference reduces the intrinsic strength of the 3' splice site of exon 7 2-fold, whereas the strength of the 5' splice site of the exon 7 is not affected. Thus, a decrease in splice site strength is magnified in the context of competing exons. These data suggest that lower levels of exon 7 definition not only reduce intron 6 removal but, more importantly, increase the efficiency of the competing exon 7 skipping pathway. Antisense oligonucleotides were tested to modulate exon 7 inclusion, which contains the authentic translation stop codon. Oligonucleotides directed toward the 3' splice site of exon 8 were shown to alter SMN2 splicing in favor of exon 7 inclusion. These results suggest that antisense oligonucleotides could be used as a therapeutic strategy to counteract the progression of SMA.     

snoTARGET shows that human orphan snoRNA targets locate close to alternative splice junctions

Among thousands of non-protein-coding RNAs which have been found in humans, a significant group represents snoRNA molecules that guide other types of RNAs to specific chemical modifications, cleavages, or proper folding. Yet, hundreds of mammalian snoRNAs have unknown function and are referred to as "orphan" molecules. In 2006, for the first time, it was shown that a particular orphan snoRNA (HBII-52) plays an important role in the regulation of alternative splicing of the serotonin receptor gene in humans and other mammals. In order to facilitate the investigation of possible involvement of snoRNAs in the regulation of pre-mRNA processing, we developed a new computational web resource, snoTARGET, which searches for possible guiding sites for snoRNAs among the entire set of human and rodent exonic and intronic sequences. Application of snoTARGET for finding possible guiding sites for a number of human and rodent orphan C/D-box snoRNAs showed that another subgroup of these molecules (HBII-85) have statistically elevated guiding preferences toward exons compared to introns. Moreover, these energetically favorable putative targets of HBII-85 snoRNAs are non-randomly associated with genes producing alternatively spliced mRNA isoforms. The snoTARGET resource is freely available at: (http://hsc.utoledo.edu/depts/bioinfo/snotarget.html).     

Integrative genome-wide analysis reveals cooperative regulation of alternative splicing by hnRNP proteins

Understanding how RNA binding proteins control the splicing code is fundamental to human biology and disease. Here, we present a comprehensive study to elucidate how heterogeneous nuclear ribonucleoparticle (hnRNP) proteins, among the most abundant RNA binding proteins, coordinate to regulate alternative pre-mRNA splicing (AS) in human cells. Using splicing-sensitive microarrays, crosslinking and immunoprecipitation coupled with high-throughput sequencing (CLIP-seq), and cDNA sequencing, we find that more than half of all AS events are regulated by multiple hnRNP proteins and that some combinations of hnRNP proteins exhibit significant synergy, whereas others act antagonistically. Our analyses reveal position-dependent RNA splicing maps, in vivo consensus binding sites, a surprising level of cross- and autoregulation among hnRNP proteins, and the coordinated regulation by hnRNP proteins of dozens of other RNA binding proteins and genes associated with cancer. Our findings define an unprecedented degree of complexity and compensatory relationships among hnRNP proteins and their splicing targets that likely confer robustness to cells.     

The splice of life: alternative splicing and neurological disease

Splicing of pre-messenger RNA is regulated differently in the brain compared with other tissues. Recognition of aberrations in splicing events that are associated with neurological disease has contributed to our understanding of disease pathogenesis in some cases. Neuron-specific proteins involved in RNA splicing and metabolism are also affected in several neurological disorders. These findings have begun to bridge what we know about the mechanisms regulating neuron-specific splicing and our understanding of neural function and disease.     

The role of the polypyrimidine stretch at the SV40 early pre-mRNA 3'' splice site in alternative splicing.

We have studied the role in pre-mRNA splicing of the nucleotide sequence preceding the SV40 early region 3' splice site. Somewhat surprisingly, neither the pyrimidine at the highly conserved -3 position, nor the polypyrimidine stretch that extends from -5 to -15, relative to the 3' splice site, were found to be required for efficient splicing. Mutations that delete this region or create polypurine insertions at position -2 had no significant effects on the efficiency of SV40 early pre-mRNA splicing in vivo or in vitro. Interestingly, however, the pyrimidine content of this region had substantial effects on the alternative splicing pattern of this pre-mRNA in vivo. Mutations that increased the number of pyrimidine residues resulted in more efficient utilization of the large T antigen mRNA 5' splice site relative to the small t 5' splice site, while mutations that increased the purine content enhanced small t mRNA splicing. A possible molecular mechanism for these findings, as well as a model that proposes a role for the polypyrimidine stretch in alternative splicing, are discussed.     

Genomic structure and alternative splicing of chicken angiopoietin-2

Angiopoietin-1 (Ang-1) prevents endothelial cell apoptosis and promotes blood vessel stability, while angiopoietin-2 (Ang-2), a natural antagonist of Ang-1, disrupts blood vessel structure and induces apoptosis. We have sequenced the chicken angiopoietin-2 gene that spans about 46 kb of DNA and is split in 9 exons by 8 introns. Alternative splicing of the gene gives rise to three different species of Ang-2 mRNAs: Ang-2A, Ang-2B, and Ang-2C. The three mRNA isoforms, also present in humans, codify for proteins with an identical fibrinogen-like C-terminal domain and a different coiled-coil N-terminal domain. Ang-2A and particularly Ang-2C are expressed in immature testis and regressed adult testis undergoing vascular remodeling, while their expression is barely detectable in quiescent adult testis. Conversely, Ang-2B is only detectable in adult testis. The new isoforms with truncated amino-terminal domains may modulate the Tie2 receptor during vascular angiogenesis and regression.     

Substrate recognition and splice site determination in yeast tRNA splicing

S. cerevisae tRNA introns interrupt the gene at a constant position in the anticodon loop. Pre-tRNAs are matured by an endonuclease and a ligase. The endonuclease alone can accurately release the intron from the pre-tRNA. Here, we investigate the mechanism of splice site selection by the endonuclease. We propose that it initially recognizes features in the mature domain common to all tRNAs. Once positioned on the enzyme, the splice sites are recognizable because they are a fixed distance from the mature domain. To test this hypothesis, we developed a system for synthesizing pre-tRNA by bacteriophage T7 RNA polymerase. To search for recognition sites, we made several mutations. Mutations of C56 and U8 strongly affect endonuclease recognition of pre-tRNA. With insertion and deletion mutations, we show that the anticodon stem determines splicing specificity. The sequence and structure of the intron are not strong determinants of splice site selection.