Alternative splicing is a potent regulator of gene expression that vastly increases proteomic diversity in multicellular eukaryotes and is associated with organismal complexity. Although alternative splicing is widespread in vertebrates, little is known about the evolutionary origins of this process, in part because of the absence of phylogenetically conserved events that cross major eukaryotic clades. Here we describe a lariat-sequencing approach, which offers high sensitivity for detecting splicing events, and its application to the unicellular fungus, Schizosaccharomyces pombe, an organism that shares many of the hallmarks of alternative splicing in mammalian systems but for which no previous examples of exon-skipping had been demonstrated. Over 200 previously unannotated splicing events were identified, including examples of regulated alternative splicing. Remarkably, an evolutionary analysis of four of the exons identified here as subject to skipping in S. pombe reveals high sequence conservation and perfect length conservation with their homologs in scores of plants, animals, and fungi. Moreover, alternative splicing of two of these exons have been documented in multiple vertebrate organisms, making these the first demonstrations of identical alternative-splicing patterns in species that are separated by over 1 billion y of evolution.pre-mRNA splicing | post-transcriptional gene regulation | phylogeny T he protein coding regions of eukaryotic genes are typically interrupted by noncoding introns that must be removed to produce a translatable mRNA. The removal of introns, catalyzed by the spliceosome, offers a powerful opportunity for an organism to regulate gene expression. In mammals, where individual genes are often interrupted by multiple introns, it is now abundantly clear that the process of intron removal provides a critical regulatory control point for both qualitative and quantitative aspects of gene expression (1). By changing the identity of the exons that are included within the final mRNA, the process of alternative splicing plays a critical role in expanding the diversity of proteins that can be synthesized within a cell (2). Moreover, alternative splicing can direct the production of isoforms of genes that are directly targeted to cellular decay pathways, providing a mechanism to quantitatively regulate gene expression (3, 4).In mammalian organisms the predominant form of alternative splicing is exon skipping, wherein different combinations of exons are included in the final transcript. In contrast, exon skipping is far less prevalent in simpler eukaryotes (5, 6); however, recent studies suggest that splicing in the last eukaryotic common ancestor was similar in many respects to splicing in vertebrates, in so much as it was intron-dense (7-9), had degenerate splice site sequences (10), and likely had many of the proteins involved in alternative splicing (11,12). Intron density correlates positively with the prevalence of alternative splicing across the eukaryotic kingdoms (13), and thus it has...
