Genetic and biochemical studies of Schizosaccharomyces pombe and Saccharomyces cerevisiae have identified gene products that play essential functions in both pre-mRNA splicing and cell cycle control. Among these are the conserved, Myb-related CDC5 (also known as Cef1p in S. cerevisiae) proteins. The mechanism by which loss of CDC5/Cef1p function causes both splicing and cell cycle defects has been unclear. Here we provide evidence that cell cycle arrest in a new temperature-sensitive CEF1 mutant, cef1-13, is an indirect consequence of defects in pre-mRNA splicing. Although cef1-13 cells harbor global defects in pre-mRNA splicing discovered through intron microarray analysis, inefficient splicing of the ␣-tubulin-encoding TUB1 mRNA was considered as a potential cause of the cef1-13 cell cycle arrest because cef1-13 cells arrest uniformly at G 2 /M with many hallmarks of a defective microtubule cytoskeleton. Consistent with this possibility, cef1-13 cells possess reduced levels of total TUB1 mRNA and ␣-tubulin protein. Removing the intron from TUB1 in cef1-13 cells boosts TUB1 mRNA and ␣-tubulin expression to near wild-type levels and restores microtubule stability in the cef1-13 mutant. As a result, cef1-13 tub1⌬i cells progress through mitosis and their cell cycle arrest phenotype is alleviated. Removing the TUB1 intron from two other splicing mutants that arrest at G 2 /M, prp17⌬ and prp22-1 strains, permits nuclear division, but suppression of the cell cycle block is less efficient. Our data raise the possibility that although cell cycle arrest phenotypes in prp mutants can be explained by defects in pre-mRNA splicing, the transcript(s) whose inefficient splicing contributes to cell cycle arrest is likely to be prp mutant dependent.Pre-mRNA splicing and cell cycle regulation have two distinct and apparently nonoverlapping functions for eukaryotic cells. In spite of this, a handful of genes in Saccharomyces cerevisiae and Schizosaccharomyces pombe have been identified in genetic screens for splicing factors (prp screens) and independently in screens for cell cycle regulators (cdc and related screens). These genes include S. cerevisiae PRP3 (also known as DBF5), PRP8 (also known as DBF3), PRP17 (also known as CDC40), and PRP22 and S. pombe prp8 ϩ (also known as cdc28 ϩ ) and prp2 ϩ (also known as mis11 ϩ ) (24,26,29,44,49,56,57). Furthermore, several prp mutants in S. pombe display morphologies consistent with defects in cell cycle progression (36, 54). Lastly, two proteins in S. pombe, Cdc5p and Dsk1p, both of which were identified genetically as potential cell cycle regulators, have since been implicated biochemically in premRNA splicing (30,50). In higher eukaryotes, splicing factors reorganize spatially throughout the cell cycle (19), and CDK2-cyclin E phosphorylates the U2 snRNP protein, SAP155 (43). Collectively, these data raise the possibility that pre-mRNA splicing and cell cycle control are functionally linked in vivo, although the molecular mechanisms underlying this connection remain vague.The conser...
