Yukinobu Nakaseko

Fission yeast cut3 and cut14, members of a ubiquitous protein family, are required for chromosome condensation and segregation in mitosis.

Fission yeast temperature‐sensitive mutants cut3‐477 and cut14‐208 fail to condense chromosomes but small portions of the chromosomes can separate along the spindle during mitosis, producing phi‐shaped chromosomes. Septation and cell division occur in the absence of normal nuclear division, causing the cut phenotype. Fluorescence in situ hybridization demonstrated that the contraction of the chromosome arm during mitosis was defective. Mutant chromosomes are apparently not rigid enough to be transported poleward by the spindle. Loss of the cut3 protein by gene disruption fails to maintain the nuclear chromatin architecture even in interphase. Both cut3 and cut14 proteins contain a putative nucleoside triphosphate (NTP)‐binding domain and belong to the same ubiquitous protein family which includes the budding yeast Smc1 protein. The cut3 mutant was suppressed by an increase in the cut14+ gene dosage. The cut3 protein, having the highest similarity to the mouse protein, is localized in the nucleus throughout the cell cycle. Plasmids carrying the DNA topoisomerase I gene partly suppressed the temperature sensitive phenotype of cut3‐477, suggesting that the cut3 protein might be involved in chromosome DNA topology.

Composite motifs and repeat symmetry in S. pombe centromeres: Direct analysis by integration of Notl restriction sites

S. pombe centromeres are large and complex. We introduced a method that enables us to characterize directly centromere DNAs. Genomic DNA fragments containing cen1, cen2, or cen3, respectively, are made by cleaving NotI sites integrated on target sites and are partially restricted for long-range mapping in PFG electrophoresis. The 40 kb long cen1 consists of two inverted approximately 10 kb motifs, each containing centromeric elements dg and dh, flanked by a central region. In cen2, three motifs are arranged in inverted and direct orientations with flanking domains, making up the approximately 70 kb long repetitious region. In cen3, approximately 15 copies of dg-dh constitute a region longer than 100 kb. A set of inverted motifs with an approximately 15 kb central region might be a prototype for the S. pombe centromeres. The motifs appear to play a role in chromosome stability and segregation. Their action may be additive, and the mutual directions of dg and dh inside a motif may not be essential for function.

Rapamycin sensitivity of the Schizosaccharomyces pombe tor2 mutant and organization of two highly phosphorylated TOR complexes by specific and common subunits

Nutrients are essential for cell growth and division. Screening of Schizosaccharomyces pombe temperature‐sensitive strains led to the isolation of a nutrient‐insensitive mutant, tor2‐287. This mutant produces a nitrogen starvation‐induced arrest phenotype in rich media, fails to recover from the arrest, and is hypersensitive to rapamycin. The L2048S substitution mutation in the catalytic domain in close proximity to the adenine base of ATP is unique as it is the sole known genetic cause of rapamycin hypersensitivity. Localization of Tor2 was speckled in the vegetative cytoplasm, and both speckled and membranous in the arrested cell cytoplasm. Using mass spectroscopic analysis, we identified six subunits (Tco89, Bit61, Toc1, Tel2, Tti1 and Cka1) that, in addition to the six previously identified subunits (Tor1, Tor2, Mip1/Raptor, Ste20/Rictor, Sin1/Avo1 and Wat1/Lst8), comprise the TOR complexes (TORCs). All of the subunits so far examined are multiply phosphorylated. Tel2 bound to Tti1 interacts with various phosphatidyl inositol kinase (PIK)‐related kinases including Tra1, Tra2 and Rad3, as well as Tor1 and Tor2. Schizosaccharomyces pombe TORCs should thus be functionally redundant and might be broadly regulated through different subunits that are either common or specific to the two TORCs, or even common to various PIK‐related kinases. Functional redundancy of the TORCs may explain the rapamycin hypersensitivity of tor2‐287.

Chromosome walking shows a highly homologous repetitive sequence present in all the centromere regions of fission yeast

By cloning centromere‐linked genes followed by partial overlapping hybridization, we constructed a 210‐kb map encompassing the centromere in chromosome II and a 60‐kb map near the centromere of chromosome I in the fission yeast Schizosaccharomyces pombe which has three chromosomes. Integration of the cloned sequences onto the chromosome and subsequent analyses of tetrads and dyads revealed an ∼50 kb long domain located in the middle of the 210‐kb map, tightly linked to the centromere and greatly reduced in meiotic recombination. This domain contained at least two classes of repetitive sequences. One, designated yn1, was specifically present in a particular chromosome and repeated three times in the 210‐kb map of chromosome II. The other, designated dg, was located in all the centromere regions of three chromosomes. One (dgI) and two (dgIIa, dgIIb) copies of the dg were found in the maps of chromosomes I and II, respectively. The dgIIa and dgIIb were arranged with a 20‐kb interval within the repetitive domain. In the centric region of chromosome III, 3−4 copies of the dg appeared to exist. By determining the nucleotide sequences of dgI and dgIIa, the dg was identified to be 3.8 kb long. The sequence homology was 99% between dgI and dgIIa. These extraordinarily homologous sequences seemed not to be transcribed into RNA nor to be encoding any protein. The larger part of the dg sequence was internally non‐repetitious, a 600‐bp region existed which consisted of stretches of several short repeating units. The structures in or surrounding the centromeres of S. pombe appear to be much more complex than those of the budding yeast Saccharomyces cerevisiae.

M phase–specific kinetochore proteins in fission yeast: Microtubule-associating Dis1 and Mtc1 display rapid separation and segregation during anaphase

BACKGROUND Kinetochore microtubules are made early in mitosis and link chromosomal kinetochores to the spindle poles. They are required later to move the separated sister chromatids toward the opposite poles upon the onset of anaphase. Very little is known about proteins that are responsible for the connection between kinetochores and mitotic microtubules. RESULTS We here show that fission yeast Dis1 and the related protein Mtc1/Alp14 are both able to bind microtubules in vitro and share an essential function for viability in vivo. The deletion of mtc1+ results in an instability of cytoplasmic microtubules that can be suppressed by the ectopic expression of dis1+. Dis1 and Mtc1 are localized along interphase cytoplasmic microtubules and are mobilized onto the spindle upon mitotic commitment. In chromatin immunoprecipitation (CHIP) experiments Dis1 coprecipitated with the central centromeric DNA in an M phase-specific manner. Consistently, observations of both living cells in which the native, genomic copy of dis1+ tagged with GFP and cells fixed by immunostaining established that Dis1 behaves as a kinetochore protein during the progression from metaphase to anaphase. The central and C-terminal regions of Dis1 are sufficient for interactions with microtubules and the kinetochore, respectively. In anaphase, the GFP signals of both Dis1 and Mtc1 suddenly separate and move quickly toward opposite spindle poles. CONCLUSIONS Fission yeast Dis1 and Mtc1 are members of an evolutionarily conserved microtubule binding protein family that includes frog XMAP215. Dis1 and Mtc1 are implicated in stabilizing kinetochore microtubules in metaphase and so counteract the action of microtubule destabilizing factors that dominate in anaphase. Dis1 may play a dual role by becoming a part of the kinetochores in an M phase-specific manner, and it may possibly generate connections between kinetochores and microtubules.

Genetic control of cellular quiescence in S. pombe

Transition from proliferation to quiescence brings about extensive changes in cellular behavior and structure. However, the genes that are crucial for establishing and/or maintaining quiescence are largely unknown. The fission yeast Schizosaccharomyces pombe is an excellent model in which to study this problem, because it becomes quiescent under nitrogen starvation. Here, we characterize 610 temperature-sensitive mutants, and identify 33 genes that are required for entry into and maintenance of quiescence. These genes cover a broad range of cellular functions in the cytoplasm, membrane and nucleus. They encode proteins for stress-responsive and cell-cycle kinase signaling pathways, for actin-bound and osmo-controlling endosome formation, for RNA transcription, splicing and ribosome biogenesis, for chromatin silencing, for biosynthesis of lipids and ATP, for cell-wall and membrane morphogenesis, and for protein trafficking and vesicle fusion. We specifically highlight Fcp1, a CTD phosphatase of RNA polymerase II, which differentially affects the transcription of genes that are involved in quiescence and proliferation. We propose that the transcriptional role of Fcp1 is central in differentiating quiescence from proliferation.

Schizosaccharomyces pombe cell division cycle under limited glucose requires Ssp1 kinase, the putative CaMKK, and Sds23, a PP2A-related phosphatase inhibitor

Calcium/calmodulin‐dependent protein kinase (CaMK) is required for diverse cellular functions, and similar kinases exist in fungi. Although mammalian CaMK kinase (CaMKK) activates CaMK and also evolutionarily‐conserved AMP‐activated protein kinase (AMPK), CaMKK is yet to be established in yeast. We here report that the fission yeast Schizosaccharomyces pombe Ssp1 kinase, which controls G2/M transition and response to stress, is the putative CaMKK. Ssp1 has a CaM binding domain (CBD) and associates with 14‐3‐3 proteins as mammalian CaMKK does. Temperature‐sensitive ssp1 mutants isolated are defective in the tolerance to limited glucose, and this tolerance requires the conserved stretch present between the kinase domain and CBD. Sds23, multi‐copy suppressor for mutants defective in type 1 phosphatase and APC/cyclosome, also suppresses the ssp1 phenotype, and is required for the tolerance to limited glucose. We demonstrate that Sds23 binds to type 2A protein phosphatases (PP2A) and PP2A‐related phosphatase Ppe1, and that Sds23 inhibits Ppe1 phosphatase activity. Ssp1 and Ppe1 thus seem to antagonize in utilizing limited glucose. We also show that Ppk9 and Ssp2 are the catalytic subunits of AMPK and AMPK‐related kinases, respectively, which bind to common β‐(Amk2) and γ‐(Cbs2) subunits.

Dissection of fission yeast microtubule associating protein p93Dis1: regions implicated in regulated localization and microtubule interaction

Background: Fission yeast microtubule associating protein (MAP) p93Dis1 functions for sister chromatid separation: dis1 mutants fail to separate chromosomes, while the spindle elongates but without cyclin destruction. p93Dis1 localizes along microtubules in interphase cytoplasm, but shifts to the spindle pole body (SPB) and spindle microtubules upon the entry into mitosis. In this study, regions of p93Dis1 were dissected to examine their role.

Mapping of rRNA genes by integration of hybrid plasmids in Schizosaccharomyces pombe.

SummaryThe major rRNA genes of the fission yeast Schizosaccharomyces pombe were mapped on chromosome III by plasmid integration. The integration vector YIp33 containing S. cerevisiae LEU2 gene was combined with the S. pombe rDNA. Since LEU2 complements S. pombe leu1 deficiency, it could be used as the genetic marker for integration. The 10.4 kb rDNA repeat contained ARS sequence, and therefore 2.4 kb and 0.7 kb subfragments not containing ARS were subcloned into YIp33 and transformed leu1 S. pombe cells to Leu+. Genetic analyses of the transformants indicated that the integrated rDNA resides in the long arm of the shortest chromosome III, tightly linked to ade5 (1.4 cM). This result is consistent with our previous finding that the DAPI-stained smallest chromosomes were associated with the nucleolus (Umesono et al. 1983).

Mapping epigenetic mutations in fission yeast using whole-genome next-generation sequencing

Fission yeast is an important model for epigenetic studies due to the ease with which genetic mutants can be isolated. However, it can be difficult to complement epigenetic phenotypes with genomic libraries in order to identify the genes responsible. This is because epigenetic phenotypes are typically unstable, and can prohibit complementation if silencing cannot be reestablished. Here we have resequenced the fission yeast genome following mutagenesis to readily identify a novel mutant involved in heterochromatic silencing. Candidate genes were identified as functional single base changes linked to the mutation, which were then reconstituted in a wild-type strain to recapitulate the mutant phenotype. By this procedure we identified a weak allele of ubc4, which encodes an essential E2 ubiquitin ligase, as responsible for the swi*603 mutant phenotype. In combination with a large collection of mutants and suppressor plasmids, next-generation genomic resequencing promises to dramatically enhance the power of yeast genetics, permitting the isolation of subtle alleles of essential genes, alleles with quantitative effects, and enhancers and suppressors of heterochromatic silencing.