SOX2 modulates alternative splicing in transitional cell carcinoma

Aberrant alternative splicing of key cellular regulators may play a pivotal role in cancer development. To investigate the potential influence of altered alternative splicing on the development of transitional cell carcinoma (TCC), splicing activity in the TCC cell lines TSGH8301 and BFTC905 was examined using the SV40-immortalized uroepithelial cell line SV-HUC-1 as a reference. Our results indicate a significant alteration in splice site selection in the TCC cell lines. By gene expression profiling and subsequent validation, we discovered that sex-determining region Y-box protein 2 (SOX2) is specifically upregulated in BFTC905. Furthermore, ectopic expression of SOX2 modulates alternative splicing of the splicing reporter in vivo. More significantly, using an in vitro pull-down assay, it was found that SOX2 exhibits RNA-binding capability. Our observations suggest that SOX2 modulates alternative splicing by functioning as a splicing factor.     

Loss of Pnn expression attenuates expression levels of SR family splicing factors and modulates alternative pre-mRNA splicing in vivo

SR and SR-related proteins have been implicated as trans-acting factors that play an important role in splice selection and are involved at specific stages of spliceosome formation. A well-established property of SR protein splicing factors is their ability to influence selection of alternative splice sites in a concentration-dependent manner. Identification of molecules that regulate SR family protein expression is therefore of vital importance in RNA biology. Here we report that depletion of Pnn expression, a SR-related protein with functions involved in pre-mRNA splicing and mRNA export, induces reduced expression of a subset of cellular proteins, especially that of SR family proteins, including SC35, SRm300, SRp55, and SRp40, but not that of other nuclear proteins, such as p53, Mdm2, and ki67. Knocking down Pnn expression was achieved in vitro by siRNA transfection. Expression levels of SR and SR-related proteins in Pnn-depleted cells as compared to those in control cells were evaluated by immunofluorescent staining and Western blot with specific antibodies. In addition, we also demonstrate that loss of Pnn expression could modulate splice site selection of model reporter gene in vivo. Our finding is significant in terms of regulation of SR protein cellular concentration because it reveals that Pnn may play a general role in the control of the cellular amount of family SR proteins through down-regulation of its own expression, thereby providing us with a better understanding of the cellular mechanism by which Pnn fulfills its biological function.     

Modulation of alternative pre-mRNA splicing in vivo by pinin

Pre-mRNA splicing occurs in a large macromolecular RNA-protein complex called the spliceosome. The major components of the spliceosome include snRNP and SR proteins. We have previously identified an SR-like protein, pinin (pnn), which is localized not only in nuclear speckles but also at desmosomes. The nuclear localization of pnn is a dynamic process because pnn can be found not only with SR proteins in nuclear speckles but also in enlarged speckles following treatment of cells with RNA polymerase II inhibitors, DRB, and alpha-amanitin. Using adenovirus E1A and chimeric calcitonin/dhfr construct as a splicing reporter minigene in combination with cellular cotransfection, we found that pnn regulates alternative 5(') and 3(') splicing by decreasing the use of distal splice sites. Regulation of 5(') splice site choice was also observed for RNPS1, a general splicing activator that interacts with pnn in nuclear speckles. The regulatory ability of pnn in alternative 5(') splicing, however, was not dependent on RNPS1 and a pnn mutant, lacking the N-terminal 167 amino acids, behaved like a dominant negative species, inhibiting E1A splicing when applied in splicing assays. These results provide direct evidence that pnn functions as a splicing regulator which participates itself directly in splicing reaction or indirectly via other components of splicing machinery.     

RBM10 regulates alternative splicing

RBM10, originally called S1-1, is a nuclear RNA-binding protein with domains characteristic of RNA processing proteins. It has been reported that RBM10 constitutes spliceosome complexes and that RBM5, a close homologue of RBM10, regulates alternative splicing of apoptosis-related genes, Fas and cFLIP. In this study, we examined whether RBM10 has a regulatory function in splicing similar to RBM5, and determined that it indeed regulates alternative splicing of Fas and Bcl-x genes. RBM10 promotes exon skipping of Fas pre-mRNA as well as selection of an internal 5′-splice site in Bcl-x pre-mRNA. We propose a consensus RBM10-binding sequence at 5′-splice sites of target exons and a mechanistic model of RBM10 action in the alternative splicing.     

ASD及其在基因选择性剪接检索中的应用

在生物信息学的飞速发展中,与之相应的各种类型的数据库不断涌现,选择性剪接数据库（Alternative Splicing Database）便是其中之一。本文详细介绍了ASD数据库的主要内容及其功能,并在其子数据库AltSplice中检索NGAL基因的选择性剪接,由此为例说明了ASD数据库在基因选择性剪接检索中的应用。     

Visualization of alternative splicing in vivo

The analysis of sequences required for alternative splicing of mRNA has predominantly been performed using cell culture systems. However, the phenotype of cultured cells is almost invariably different from that of cells in the intact animal. It is therefore possible that there are significant differences in the regulation of specific splicing reactions in vivo compared to in cell culture. Here, we describe methods for the visualization and analysis of alternative splicing in vivo using transgenic mice. These methods allow for the analysis of the temporal and tissue-specific regulation of alternative splicing both visually and quantitatively.     

Detection and measurement of alternative splicing using splicing-sensitive microarrays

Splicing and alternative splicing are major processes in the interpretation and expression of genetic information for metazoan organisms. The study of splicing is moving from focused attention on the regulatory mechanisms of a selected set of paradigmatic alternative splicing events to questions of global integration of splicing regulation with genome and cell function. For this reason, parallel methods for detecting and measuring alternative splicing are necessary. We have adapted the splicing-sensitive oligonucleotide microarrays used to estimate splicing efficiency in yeast to the study of alternative splicing in vertebrate cells and tissues. We use gene models incorporating knowledge about splicing to design oligonucleotides specific for discriminating alternatively spliced mRNAs from each other. Here we present the main strategies for design, application, and analysis of spotted oligonucleotide arrays for detection and measurement of alternative splicing. We demonstrate these strategies using a two-intron yeast gene that has been altered to produce different amounts of alternatively spliced RNAs, as well as by profiling alternative splicing in NCI 60 cancer cell lines.