Smooth muscle alternative splicing induced in fibroblasts by heterologous expression of a regulatory gene.

Alternative splicing is a common mechanism for regulating gene expression in different cell types. In order to understand this important process, the trans-acting factors that enforce the choice of particular splicing pathways in different environments must be identified. We have used the rat alpha-tropomyosin gene as a model system of tissue-specific alternative splicing. Exon 3 of alpha-tropomyosin is specifically inhibited in smooth muscle cells allowing the alternative inclusion of exon 2. We have used a novel gene transfer and selection strategy to detect a gene whose expression in fibroblasts is sufficient to switch them to smooth muscle-specific splicing of alpha-tropomyosin and also alpha-actinin. Extracts from the regulating fibroblasts contain an apparently novel 55 kDa protein which binds to RNA elements required for regulation of tropomyosin splicing. This protein is not detected in extracts of non-regulating cells and is therefore a strong candidate cell-specific splicing regulator. These experiments advance our understanding of smooth muscle splicing regulation as well as establishing a means for direct cloning of tissue-specific splicing regulators which have so far been refractory to biochemical analysis.     

Specific expression pattern of a novel Otx2 splicing variant during neural differentiation

We cloned a new splicing variant of Otx2 gene, Otx2c. Otx2c lacks entire exon 4, most of the region encoding the homeodomain. More importantly, Otx2c harbors an early premature stop codon and bioinformatics analysis prefers it to be a non-protein coding RNA. In addition, this splicing variant is not simply a noise during mRNA processing, since it is mainly expressed in undifferentiated human embryonic stem cells but gradually decreased during differentiation. Therefore, we report here that a single pre-mRNA can generate both coding and non-coding RNAs through alternative splicing and this splicing activity is tightly regulated in different cell contexts.     

cDNA cloning of mouse myelin-associated glycoprotein: a novel alternative splicing pattern

The structures of three forms of mouse myelin-associated glycoprotein mRNAs were determined from full-length cDNA clones. Two forms of mRNAs have been reported to be different by alternate inclusion of exon 2 and 12 in rat brain. One of the three forms of clones obtained here appeared to be a novel mRNA which lacked both the exon 2 and 12 portions, although others were identical splicing patterns to those of rat. Northern blot analysis using specific probes to mRNAs with or without the exon 2 portion in normal and quaking mouse confirmed that the splicing of exon 2 and 12 occurred independently.     

Control of alternative splicing by antisense oligonucleotides as a potential chemotherapy: effects on gene expression

Expression of alternatively spliced mRNA variants at specific stages of development or in specific cells and tissues contributes to the functional diversity of the human genome. Aberrations in alternative splicing were found as a cause or a contributing factor to the development, progression, or maintenance of various diseases including cancer. The use of antisense oligonucleotides to modify aberrant expression patterns of alternatively spliced mRNAs is a novel means of potentially controlling such diseases. However, to utilize antisense oligonucleotides as molecular chemotherapeutic agents, the global effects of these molecules need to be examined. The advent of gene expression array technology has now made it possible to simultaneously examine changes that occur in the expression levels of several thousand genes in response to antisense treatment. This analysis should help in the development of more specific and efficacious antisense oligonucleotides as molecular therapeutics.