Osami Niwa

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.

Cold-sensitive and caffeine-supersensitive mutants of the Schizosaccharomyces pombe dis genes implicated in sister chromatid separation during mitosis.

We isolated novel classes of Schizosaccharomyces pombe cold‐sensitive dis mutants that block mitotic chromosome separation (nine mapped in the dis1 gene and one each in the dis2 and dis3 genes). Defective phenotype at restrictive temperature is similar among the mutants; the chromosomes condense and anomalously move to the cell ends in the absence of their disjoining so that they are unequally distributed at the two cell ends. Synchronous culture analyses indicate that the cells can enter into mitosis at normal timing but become lethal during mitosis. In comparison with the wild‐type mitosis, defects are found in the early spindle structure, the mitotic chromosome structure, the poleward chromosome movement by the spindle elongation and the telophase spindle degradation. The dis mutants lose at permissive temperature an artificial minichromosome at higher rates than occur in the wild type. We found that all the dis mutants isolated are supersensitive to caffeine at permissive temperature. Furthermore, the mutant cells in the presence of caffeine produce a phenotype similar to that obtained at restrictive temperature. We suggest that the dis genes are required for the sister chromatid separation at the time of mitosis and that caffeine might affect the dis gene expression. We cloned, in addition to the dis2+ and dis3+ genes, multicopy extragenic suppressor sequences which complement dis1 and dis2 mutations. A complex regulatory system may exist for the execution of the dis+ gene functions.

Telomere‐led bouquet formation facilitates homologous chromosome pairing and restricts ectopic interaction in fission yeast meiosis

A polarized chromosomal arrangement with clustered telomeres in a meiotic prophase nucleus is often called bouquet and is thought to be important for the pairing of homologous chromosomes. Fluorescence in situ hybridization in fission yeast indicated that chromosomal loci are positioned in an ordered manner as anticipated from the bouquet arrangement. Blocking the formation of the telomere cluster with the kms1 mutation created a disorganized chromosomal arrangement, not only for the regions proximal to the telomere but also for interstitial regions. The kms1 mutation also affected the positioning of a linear minichromosome. Consistent with this cytological observation, the frequency of ectopic homologous recombination between a linear minichromosome and a normal chromosome increased in the kms1 background. Intragenic recombination between allelic loci is reduced in the kms1 mutant, but those between non‐allelic loci are unaffected or slightly increased. Thus, telomere‐led chromosome organization facilitates homologous pairing and also restricts irregular chromosome pairing during meiosis.

Characterization of Schizosaccharomyces pombe minichromosome deletion derivatives and a functional allocation of their centromere.

A 530 kb long Schizosaccharomyces pombe linear minichromosome, Ch16, containing a centric region of chromosome III, has previously been made. In the present study, we constructed a number of deletions in the right and/or left arms of Ch16, and compared their structure and behaviour with Ch16. The functional centromere, cen3, is allocated within a 120 kb long region which is covered by the shortest derivative, Ch10, and is comprised mostly of centromeric repeating sequences. The shortest minichromosome is stable in mitosis and the copy number control is apparently precise. In monosomic meiosis it segregates normally. In disomic meioses, however, the frequency of non‐disjunction is very high, suggesting that it may not form a pair. The mitotic loss rate of one of the left‐arm deletions, ChR32, which lacks a part of the centromeric repeating sequence, is the highest of all the deletions. This deletion also exhibits the highest precocious sister chromatid separation in meiosis I, suggesting that sister chromatid association might become weakened in ChR32. Our results indicate that the proper meiotic segregation of S.pombe minichromosomes is dependent upon the formation of a bivalent. S.pombe may not have the ‘distributive segregation’ found with Saccharomyces cerevisiae minichromosomes.

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.

A NOVEL FISSION YEAST GENE, KMS1+, IS REQUIRED FOR THE FORMATION OF MEIOTIC PROPHASE-SPECIFIC NUCLEAR ARCHITECTURE

Abstract In the meiotic prophase nucleus of the fission yeast Schizosaccharomyces pombe, chromosomes are arranged in an oriented manner: telomeres cluster in close proximity to the spindle pole body (SPB), while centromeres form another cluster at some distance from the SPB. We have isolated a mutant, kms1, in which the structure of the meiotic prophase nucleus appears to be distorted. Using specific probes to localize the SPB and telomeres, multiple signals were observed in the mutant nuclei, in contrast to the case in wild-type. Genetic analysis showed that in the mutant, meiotic recombination frequency was reduced to about one-quarter of the wild-type level and meiotic segregation was impaired. This phenotype strongly suggests that the telomere-led rearrangement of chromosomal distribution that normally occurs in the fission yeast meiotic nucleus is an important prerequisite for the efficient pairing of homologous chromosomes. The kms1 mutant was also impaired in karyogamy, suggesting that the kms1+ gene is involved in SPB function. However, the kms1+ gene is dispensable for mitotic growth. The predicted amino acid sequence of the gene product shows no significant similarity to known proteins.

Construction of a mini-chromosome by deletion and its mitotic and meiotic behaviour in fission yeast

SummaryA highly stable, partial aneuploid, HM248, of the fission yeast Schizosaccharomyces pombe was obtained from the unstable aneuploid disomic for chromosome III by γ-irradiation. It contained a 500 kb mini-chromosome (designated Ch16) that was separated as a single band by pulsed field gradient electrophoresis. Genetic analysis showed that Ch16 was deleted for most of chromosome III except for the pericentric region; three centromere-linked markers encompassing the centromere region remained. This was further substantiated by integrating the cloned fragments of Ch16 DNA extracted from the agarose gel; integrations took place in the pericentric region. A 400 kb derivative (Ch16D1) was constructed which appeared to lack a part of Ch16. A single haploid cell of S. pombe could stably maintain Ch16 and Ch16D1 in addition to the three regular chromosomes. Ch16 was visualized as a minute chromosomal body in the nucleus of a β-tubulin mutant under restrictive conditions. A single copy of Ch16 was highly stable and behaved like a natural chromosome in mitosis and meiosis. The frequency of chromosomal loss was 10-4. In meiosis, it segregated independently of the regular chromosome III. Segregation of two Ch16s per cell could be monitored by specifically marked Ch16s containing the Saccharomyces cerevisiae LEU2 gene (designated Ch16LE) of the fluorouracil resistance marker (Ch16FR). Two copies of Ch16 were mitotically unstable (chromosomal loss, 10-3) and frequently failed in meiotic segregation. The frequency of meiotic recombination between the two Ch16s was greatly reduced.

Two-hybrid search for proteins that interact with Sad1 and Kms1, two membrane-bound components of the spindle pole body in fission yeast

In interphase cells of fission yeast, the spindle pole body (SPB) is thought to be connected with chromosomal centromeres by an as yet unknown mechanism that spans the nuclear membrane. To elucidate this mechanism, we performed two-hybrid screens for proteins that interact with Kms1 and Sad1, which are constitutive membrane-bound components of the SPB that interact with each other. Seven and 26 genes were identified whose products potentially interact with Kms1 and Sad1, respectively. With the exception of Dlc1 (a homolog of the 14-kDa dynein light chain), all of the Kms1 interactors also interacted with Sad1. Among the genes identified were the previously known genes rhp9+/ crb2+, cut6+, ags1+/ mok1+, gst3+, kms2+, and sid4+. The products of kms2+ and sid4+ localize to the SPB. The novel genes were characterized by constructing disruption mutations and by localization of the gene products. Two of them, putative homologues of budding yeast UFE1 (which encodes a t-SNARE) and SFH1 (an essential component of a chromatin-remodeling complex), were essential for viability. Two further genes, which were only conditionally essential, genetically interact with sad1+. One of these was named sif1+ (for Sad1-interacting factor) and is required for proper septum formation at high temperature. Cells in which this gene was overexpressed displayed a wee -like phenotype. The product of the other gene, apm1+, is very similar to the medium chain of an adaptor protein complex in clathrin-coated vesicles. Apm1 appears to be required for SPB separation and spindle formation, and tended to accumulate at the SPB when it was overproduced. It was functionally distinct from its homologues Apm2 and Apm4. Other novel genes identified in this study included one for a nucleoporin and genes encoding novel membrane-bound proteins that were genetically related to Sad1. We found that none of the newly identified genes tested were necessary for centromere/telomere clustering.

An evolutionarily conserved fission yeast protein, Ned1, implicated in normal nuclear morphology and chromosome stability, interacts with Dis3, Pim1/RCC1 and an essential nucleoporin.

We identified a novel fission yeast gene, ned1+, with pleiotropic mutations that have a high incidence of chromosome missegregation, aberrantly shaped nuclei, overdeveloped endoplasmic reticulum-like membranes, and increased sensitivity to a microtubule destabilizing agent. Ned1 protein, which was phosphorylated in a growth-related manner, interacted in a yeast two-hybrid system with Dis3 as well as with Pim1/RCC1 (nucleotide exchange factor for Ran). Ned1 also interacted with an essential nucleoporin, a probable homologue of mammalian Nup98/96. The ned1 gene displayed a variety of genetic interactions with factors involved in nuclear transport and chromosome segregation, including the crm1 (exportin), spi1 (small GTPase Ran), pim1, and dis genes. A substitution mutation that affected the two-hybrid interaction with Dis3 increased chromosome instability, suggesting the functional importance of the interaction. Overproduction of Ned1 protein induced formation of an abnormal microtubule bundle within the nucleus, apparently independently of the spindle pole body, but dependent on pim1+ activity. The ned1+ gene belongs to an evolutionarily conserved gene family, which includes the mouse Lpin genes, one of whose mutations is responsible for lipodystrophy.

Differential expressions of essential and nonessential alpha-tubulin genes in Schizosaccharomyces pombe.

The fission yeast Schizosaccharomyces pombe has two alpha-tubulin genes and one beta-tubulin gene. Gene disruption experiments showed that the alpha 1-tubulin gene (NDA2) is essential whereas the alpha 2 gene is dispensable. The alpha 2-disrupted cells missing alpha 2 transcript and alpha 2 polypeptide could grow and sporulate normally. The alpha 2 gene, however, was expressed in the wild type and the alpha 1 mutant. Alpha 2-Tubulin was distinguished as an electrophoretic band and was assembled into microtubules. The alpha 2-disrupted cells had an increased sensitivity to an antimicrotubule drug thiabendazole, and the alpha 1(cold-sensitive [cs]) alpha 2 (disrupted) cells became not only cs but also temperature sensitive. Northern blot experiments indicated that alpha 2 transcription was minor and constitutive whereas alpha 1 transcription was major and modulated, depending on the gene copy number of the alpha 2 gene. The amounts of alpha 1 and alpha 2 polypeptides estimated by beta-galactosidase activities of the lacZ-fused genes integrated on the chromosome and by intensities of the electrophoretic bands in crude tubulin fractions, however, were comparable, indicating that alpha 2 tubulin is not a minor subtype. We assume that the cells of Schizosaccharomyces pombe have no excess tubulin pool. alpha 1 mutants would then be blocked in the cell cycle because only half the amount of functional alpha-tubulin required for growth can be produced by the alpha 2 gene. On the other hand, the alpha 2-disrupted cells became viable because the synthesis of alpha 1 tubulin was increased by transcriptional or translational modulation or both. The real cause for essential alpha 1 and dispensable alpha 2 genes seems to be in their regulatory sequences instead of the coding sequences.