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.     

Global analysis of alternative splicing regulation by insulin and wingless signaling in Drosophila cells

Background  

Despite the prevalence and biological relevance of both signaling pathways and alternative pre-mRNA splicing, our knowledge of how intracellular signaling impacts on alternative splicing regulation remains fragmentary. We report a genome-wide analysis using splicing-sensitive microarrays of changes in alternative splicing induced by activation of two distinct signaling pathways, insulin and wingless, in Drosophila cells in culture.     

The role of alternative pre-mRNA splicing in regulating the structure and function of skeletal protein 4.1

Alternative pre-mRNA splicing plays a major role in regulating cell type-specific expression of the protein 4.1 family of skeletal proteins. The biological importance of alternative splicing as a mechanism for 4.1 gene regulation is underscored by studies of the prototypical 4.1R gene in erythroid cells: activation of exon 16 inclusion in mRna at the erythroblast stage greatly enhances the ability of newly synthesized 4.1R protein to bind spectrin and actin, and thus assemble into a stable membrane skeleton. This gain-of- function has profound effects on the biophysical properties of deformability and membrane strength that are critical to red cell survival in the circulation. Another example of developmentally regulated splicing occurs in differentiating mammary epithelial cells in culture, where cell morphogenesis is accompanied by a splicing switch that reversibly activates inclusion of alternative exon muscle. Few other genes are known to be so richly endowed with regulated switches in pre-mRna splicing making the 4.1R gene an interesting paradigm for the role of alternative splicing as a mediator of cell function. Recent evidence that other members of the 4.1 gene family are also regulated by alternative splicing suggests, moreover, that this phenomenon is of general importance in regulating the structure of this class of skeletal proteins.     

Tra2β1蛋白在神经特异性的基因剪接中的功能

体外(in vitro)生化研究已证明哺乳动物Tra2蛋白是前体mRNA剪接的重要调控因子,但是,对该蛋白在in vivo条件下的剪接功能,尤其是在神经特异性基因剪接中的功能及其细胞特异性,目前所知甚少。本文采用in vivo分析模型,在COS-l和PFSK两种不同类型的细胞中,研究了两个神经特异性基因(GluR-B,SMN2)剪接的细胞特异性,同时分析了Tra2β1在这两个基因剪接中的功能及其细胞特异性。结果表明,在研究的两种细胞中,GluR-B和SMN2“小基因”的剪接均具有明显的细胞特异性;而Tra2β1蛋白的过量表达在这两种不同的细胞中对“小基因”的剪接有显著的相同倾向的调节作用,提示Tra2β1蛋白对该两个基因剪接的调节作用可能没有细胞特异性。     

A bichromatic fluorescent reporter for cell-based screens of alternative splicing

Alternative splicing is the primary source of proteome complexity in metazoans and its regulation shapes the proteome in response to shifting physiological requirements. We developed a bichromatic splicing reporter that uses a peculiar feature of some fluorescent protein coding regions to express two different fluorescent proteins from a single alternative splicing event. The mutually exclusive expression of different fluorescent proteins from a single reporter provides a uniquely sensitive approach for high-throughput screening and analysis of cell-specific splicing events in mixed cell cultures and tissues of transgenic animals. This reporter is applicable to the majority of alternative splicing patterns and can be used to quantify alternative splicing within single cells and to select cells that express specific splicing patterns. The ability to perform quantitative single-cell analysis of alternative splicing and high-throughput screens will enhance progress toward understanding splicing regulatory networks and identifying compounds that reverse pathogenic splicing defects.     

Fluorescence-based alternative splicing reporters for the study of epithelial plasticity in vivo

Alternative splicing generates a vast diversity of protein isoforms from a limited number of protein-coding genes, with many of the isoforms possessing unique, and even contrasting, functions. Fluorescence-based splicing reporters have the potential to facilitate studies of alternative splicing at the single-cell level and can provide valuable information on phenotypic transitions in almost real time. Fibroblast growth factor receptor 2 (FGFR2) pre-mRNA is alternatively spliced to form the epithelial-specific and mesenchymal-specific IIIb and IIIc isoforms, respectively, which are useful markers of epithelial–mesenchymal transitions (EMT). We have used our knowledge of FGFR2 splicing regulation to develop a fluorescence-based reporter system to visualize exon IIIc regulation in vitro and in vivo. Here we show the application of this reporter system to the study of EMT in vitro in cell culture and in vivo in transgenic mice harboring these splicing constructs. In explant studies, the reporters revealed that FGFR2 isoform switching is not required for keratinocyte migration during cutaneous wound closure. Our results demonstrate the value of the splicing reporters as tools to study phenotypic transitions and cell fates at single cell resolution. Moreover, our data suggest that keratinocytes migrate efficiently in the absence of a complete EMT.     

Efficient in vivo manipulation of alternative pre-mRNA splicing events using antisense morpholinos in mice

Mammalian pre-mRNA alternative splicing mechanisms are typically studied using artificial minigenes in cultured cells, conditions that may not accurately reflect the physiological context of either the pre-mRNA or the splicing machinery. Here, we describe a strategy to investigate splicing of normal endogenous full-length pre-mRNAs under physiological conditions in live mice. This approach employs antisense vivo-morpholinos (vMOs) to mask cis-regulatory sequences or to disrupt splicing factor expression, allowing functional evaluation of splicing regulation in vivo. We applied this strategy to gain mechanistic insight into alternative splicing events involving exons 2 and 16 (E2 and E16) that control the structure and function of cytoskeletal protein 4.1R. In several mouse tissues, inclusion of E16 was substantially inhibited by interfering with a splicing enhancer mechanism using a target protector morpholino that blocked Fox2-dependent splicing enhancers in intron 16 or a splice-blocking morpholino that disrupted Fox2 expression directly. For E2, alternative 3'-splice site choice is coordinated with upstream promoter use across a long 5'-intron such that E1A splices almost exclusively to the distal acceptor (E2dis). vMOs were used to test the in vivo relevance of a deep intron element previously proposed to determine use of E2dis via a two-step intrasplicing model. Two independent vMOs designed against this intronic regulatory element inhibited intrasplicing, robustly switching E1A splicing to the proximal acceptor (E2prox). This finding strongly supports the in vivo physiological relevance of intrasplicing. vMOs represent a powerful tool for alternative splicing studies in vivo and may facilitate exploration of alternative splicing networks in vivo.     

Identification of cells deficient in signaling-induced alternative splicing by use of somatic cell genetics

In recent years, a growing number of mammalian genes have been shown to undergo alternative splicing in response to extracellular stimuli. However, the factors and pathways involved in such signal-induced alternative splicing are almost entirely unknown. Here we describe a novel method for identifying candidate trans-acting factors that are involved in regulating mammalian alternative splicing, using the activation-induced alternative splicing of the human CD45 gene in T cells as a model system. We generated a cell line that stably expresses a CD45 minigene-based GFP reporter construct, such that the levels of green-fluorescent protein (GFP) expressed in the cell reflect the splicing state of the endogenous CD45 gene. Following mutagenesis of this cell line, and multiple rounds of selection for cells that displayed aberrant levels of GFP expression, we isolated several cell lines that are at least partially defective in their ability to support regulated alternative splicing of endogenous CD45 pre-mRNA in response to cell stimulation. Thus we have successfully isolated mutants in a mammalian alternative splicing pathway through use of a somatic cell-based genetic screen. This study clearly demonstrates the feasibility of using genetic screens to further our understanding of the regulation of mammalian splicing, particularly as it occurs in response to environmental cues.     

Intronic alternative splicing regulators identified by comparative genomics in nematodes

Many alternative splicing events are regulated by pentameric and hexameric intronic sequences that serve as binding sites for splicing regulatory factors. We hypothesized that intronic elements that regulate alternative splicing are under selective pressure for evolutionary conservation. Using a Wobble Aware Bulk Aligner genomic alignment of Caenorhabditis elegans and Caenorhabditis briggsae, we identified 147 alternatively spliced cassette exons that exhibit short regions of high nucleotide conservation in the introns flanking the alternative exon. In vivo experiments on the alternatively spliced let-2 gene confirm that these conserved regions can be important for alternative splicing regulation. Conserved intronic element sequences were collected into a dataset and the occurrence of each pentamer and hexamer motif was counted. We compared the frequency of pentamers and hexamers in the conserved intronic elements to a dataset of all C. elegans intron sequences in order to identify short intronic motifs that are more likely to be associated with alternative splicing. High-scoring motifs were examined for upstream or downstream preferences in introns surrounding alternative exons. Many of the high- scoring nematode pentamer and hexamer motifs correspond to known mammalian splicing regulatory sequences, such as (T)GCATG, indicating that the mechanism of alternative splicing regulation is well conserved in metazoans. A comparison of the analysis of the conserved intronic elements, and analysis of the entire introns flanking these same exons, reveals that focusing on intronic conservation can increase the sensitivity of detecting putative splicing regulatory motifs. This approach also identified novel sequences whose role in splicing is under investigation and has allowed us to take a step forward in defining a catalog of splicing regulatory elements for an organism. In vivo experiments confirm that one novel high-scoring sequence from our analysis, (T)CTATC, is important for alternative splicing regulation of the unc-52 gene.     

A protocol for imaging alternative splicing regulation in vivo using fluorescence reporters in transgenic mice

Imaging technologies are influencing the way we study regulatory processes in vivo. Several recent reports use fluorescence minigenes to image alternative splicing events in living cells and animals. This type of reporter is being used to generate transgenic mice to visualize splicing regulation in diverse tissues and cell types. In this protocol, we describe how to develop animals that report on alternative splicing and how to assess reporter expression in excised organs and tissue sections. The entire procedure, from making the reporters to imaging organs and tissues in adult transgenic mice, should take approximately 1.5 years. Fluorescence reporters can be used to image many splicing decisions in normal tissues and organs and can be extended to the study of disease states.     

Muscle-specific exonic splicing silencer for exon exclusion in human ATP synthase gamma-subunit pre-mRNA.

Mitochondrial ATP synthase gamma-subunit (F(1)gamma) pre-mRNA undergoes alternative splicing in a tissue- or cell type-specific manner. Exon 9 of F(1)gamma pre-mRNA is specifically excluded in heart and skeletal muscle tissues and in acid-stimulated human fibrosarcoma HT1080 cells, rhabdomyosarcoma KYM-1 cells, and mouse myoblast C2C12 cells. Recently, we found a purine-rich exonic splicing enhancer (ESE) element on exon 9 via transgenic mice bearing F(1)gamma mutant minigenes and demonstrated that this ESE functions ubiquitously with exception of muscle tissue (Ichida, M., Hakamata, Y., Hayakawa, M., Ueno E., Ikeda, U., Shimada, K., Hamamoto, T., Kagawa, Y., Endo, H. (2000) J. Biol. Chem. 275, 15992-16001). Here, we identified an exonic negative regulatory element responsible for muscle-specific exclusion of exon 9 using both in vitro and in vivo splicing systems. A supplementation assay with nuclear extracts from HeLa cells and acid-stimulated HT1080 cells was performed for an in vitro reaction of muscle-specific alternative splicing of F(1)gamma minigene and revealed that the splicing reaction between exons 8 and 9 was the key step for regulation of muscle-specific exon exclusion. Polypyrimidine tract in intron 8 requires ESE on exon 9 for constitutive splice site selection. Mutation analyses on the F(1)gammaEx8-9 minigene using a supplementation assay demonstrated that the muscle-specific negative regulatory element is positioned in the middle region of exon 9, immediately downstream from ESE. Detailed mutation analyses identified seven nucleotides (5'-AGUUCCA-3') as a negative regulatory element responsible for muscle-specific exon exclusion. This element was shown to cause exon skipping in in vivo splicing systems using acid-stimulated HT1080 cells after transient transfection of several mutant F(1)gammaEx8-9-10 minigenes. These results demonstrated that the 5'-AGUUCCA-3' immediately downstream from ESE is a muscle-specific exonic splicing silencer (MS-ESS) responsible for exclusion of exon 9 in vivo and in vitro.