The identification of cDNAs that affect the mitosis-to-interphase transition in Schizosaccharomyces pombe, including sbp1, which encodes a spi1p-GTP-binding protein.

Perturbations of the spi1p GTPase system in fission yeast, caused by mutation or overexpression of several regulatory proteins, result in a unique terminal phenotype that includes condensed chromosomes, a wide medial septum, and a fragmented nuclear envelope. To identify potential regulators or targets of the spi1p GTPase system, a screen for cDNAs whose overexpression results in this terminal phenotype was conducted, and seven clones that represent three genes, named med1, med2, and med3 (mitotic exit defect), were identified. Their genetic interaction with the spi1p GTPase system was established by showing that the spi1p guanine nucleotide exchange factor mutant pim1-d1ts was hypersensitive to their overexpression. med1 encodes a homologue of the human Ran-binding protein, RanBP1, and has been renamed sbp1 (spi1-binding protein). sbp1p binds to spi1p-GTP and costimulates the GTPase-activating protein (GAP)-catalyzed GTPase activity. Cells in which sbp1p is depleted or overproduced phenocopy cells in which the balance between spi1p-GTP and spi1p-GDP is perturbed by other means. Therefore, sbp1p mediates and/or regulates the essential functions of the spi1p GTPase system. med2 and med3 encode novel fission yeast proteins that, based on our phenotypic analyses, are likely to identify additional regulators or effectors of the spi1p GTPase system.

The role of the EST genes in yeast telomere replication.

We have recently completed a large mutant screen designed to identify new mutants of Saccharomyces cerevisiae with a telomerase-like defect. From this screen; 22 mutants were identified that mapped to three genes, called EST1, EST2 and EST3, as well as a novel EST-like mutation in a fourth gene, previously identified as CDC13. Mutations in each of these genes give rise to phenotypes that are indistinguishable from those observed when TLC1, encoding the yeast telomerase RNA, is deleted. In addition, genetic analysis indicates that all four genes function in the same pathway for telomere replication as defined by TLC1, the one known component of telomerase. This indicates that these genes encode factors that are essential in vivo for telomerase function. Genetic and biochemical analyses have shown that EST1 and CDC13 encode single-stranded telomeric DNA-binding proteins, suggesting that these two proteins may function to mediate access of telomerase to the end of the telomere.