The alternative splicing of Bcl-x generates the proapoptotic Bcl-x S protein and the antiapoptotic isoform Bcl-x L . Bcl-x splicing is coupled to signal transduction, since ceramide, hormones, and growth factors alter the ratio of the Bcl-x isoforms in different cell lines. Here we report that the protein kinase C (PKC) inhibitor and apoptotic inducer staurosporine switches the production of Bcl-x towards the x S mRNA isoform in 293 cells. The increase in Bcl-x S elicited by staurosporine likely involves signaling events that affect splicing decisions, because it requires active transcription and no new protein synthesis and is independent of caspase activation. Moreover, the increase in Bcl-x S is reproduced with more specific inhibitors of PKC. Alternative splicing of the receptor tyrosine kinase gene Axl is similarly affected by staurosporine in 293 cells. In contrast to the case for 293 cells, PKC inhibitors do not influence the alternative splicing of Bcl-x and Axl in cancer cell lines, suggesting that these cells have sustained alterations that uncouple splicing decisions from PKC-dependent signaling. Using minigenes, we show that an exonic region located upstream of the Bcl-x S 5 splice site is important to mediate the staurosporine shift in Bcl-x splicing. When transplanted to other alternative splicing units, portions of this region confer splicing modulation and responsiveness to staurosporine, suggesting the existence of factors that couple splicing decisions with PKC signaling.Alternative splicing of pre-mRNAs provides a powerful mechanism to augment the protein repertoire encoded by metazoan genomes. It is estimated that 74% of all multiexonic human genes are alternatively spliced (36). Moreover, alternative splicing is becoming increasingly relevant to a variety of human diseases, including cancer (60, 85). These observations justify current efforts devoted at uncovering the basic principles of alternative splicing control. Many studies have provided valuable insights into the roles of specific elements and factors in splicing modulation (7,58,84). Proteins that bind to specific sequence elements to affect splice site selection include SR proteins, hnRNP proteins, and other related RNA binding proteins such as TIA-1, ETR-3, and Sam68 (16,29,35,54,59,76). Many of these proteins can be modified posttranslationally, and some of the modifications, like phosphorylation, can affect their localization and activity (59, 82).Although we expect that the coupling between signal transduction events and alternative splicing decisions will represent a major network of regulation, very little is known about how splicing is coordinated by a variety of effectors to attune cells to specific environmental demands and stresses. Possibly the first system describing a link between signal transduction and splicing involved the cell surface molecule CD44, in which exon v5 inclusion was stimulated following activation of the protein kinase C (PKC) or extracellular signal-regulated kinase, as part of the Ras signaling path...
