Fission yeast sta mutations that stabilize an unstable minichromosome are novel cdc2-interacting suppressors and are involved in regulation of spindle dynamics

Cytological observations have shown that the presence of unstable minichromosomes can delay progression through the early stages of mitosis in fission yeast (Schizosaccharomyces pombe), suggesting that such minichromosomes may provide a useful tool for examining the system that regulates the coordinated segregation of chromosomes. One such unstable minichromosome is a large circular minichromosome. We previously showed that the mitotic instability of this minichromosome is probably due to the frequent occurrence of catenated forms of DNA after replication. To identify genes involved in the regulation of chromosome behavior in mitosis, we isolated mutants which stabilized this minichromosome. Three loci (stal, sta2, and sta3) were identified. Two of them were found to be suppressors of temperature-sensitive mutations in cdc2, which encodes the catalytic subunit of muturation promoting factor (MPF). They show no linkage to, and are thus different from, sucl, and cdc13, previously identified as genes that interact with cdc2. The other mutation mapped to a gene previously identified as being required for the correct formation of the mitotic spindle. Data provided in this study suggest that the sta genes are involved in the regulation of spindle dynamics to ensure proper chromosome segregation during mitosis.     

Functional characterization of individual genomic condensin-binding sites in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> using minichromosome mitotic segregation stability assay

Proper chromatin compaction in mitosis (condensation) is required for equal chromosome distribution and the precise inheritance of genetic information. A protein complex called condensin is responsible for mitotic chromosome condensation, chromosome individualization, the timely separation of sister chromatids in mitosis, and proper tension in the mitotic spindle. The mitotic function of condensin depends on the recognition of specific binding sites in the chromosome. The mechanism for binding condensin to individual sites of mitotic chromosomes, as well as the molecular anatomy of these sites, remains to be elucidated. Even less is known about the process that translates condensin binding to individual sites into the segregation of chromosomes in anaphase. In the present work, by using minichromosome assay, we analyze seven individual condensin-binding sites in S. cerevisiae identified in the whole-genome ChIP-on-chip screening. This approach allowed us to estimate the individual contribution of condensin-binding sites to the segregation fidelity of minichromosomes.     

A large circular minichromosome of Schizosaccharomyces pombe requires a high dose of type II DNA topoisomerase for its stabilization

We have constructed circular minichromosomes, ranging in size from 36 to 110 kb, containing the centromeric repeats of Schizosaccharomyces pombe cen3. Comparison of their mitotic stability showed that the circular minichromosomes became more unstable with increasing in size, however, a linear cen3 minichromosome, which is almost the same size as the largest circular one tested, does not show such instability. High levels of expression of the top2 ⁺ (type II DNA topoisomerase; topo II) but not top1 ⁺ gene (type I DNA topoisomerase) suppressed the instability of the largest circular minichromosome, whereas partial inactivation of topo II dramatically destabilized the minichromosome. A mutant topo II, defective in nuclear localization but still retaining its in vitro relaxation activity, did not stabilize the circular minichromosome. These results indicate that endogenous type II DNA topoisomerase is insufficient for accurate segregation of the circular minichromosome. In addition, the replication of the minichromosomal DNA appears to proceed normally, because the presence of the unstable minichromosome did not cause G2 delay. A likely cause of the instability is intertwining of the minichromosome DNA possibly occuring after DNA replication. An interaction between topo II and the centromeric repeats is implied by the finding that multiple copies of the centromeric repeat, dg-dh, affect stability of the minichromosome similarly to top2 ⁺ gene dosage.     

Novel mad2 alleles isolated in a Schizosaccharomyces pombe gamma-tubulin mutant are defective in metaphase arrest activity, but remain functional for chromosome stability in unperturbed mitosis

A previously isolated fission yeast gamma-tubulin mutant containing apparently stabilized microtubules proliferated at an approximately identical rate as wild type, yet the mutant mitosis spindle dynamics were aberrant, particularly the kinetochore microtubule dynamics. Progression through mitosis in the mutant, however, resulted in mostly accurate chromosome segregation. In the absence of the spindle assembly checkpoint gene, mad2+, the spindle dynamics in the gamma-tubulin mutant were greatly compromised, leading to a high incidence of chromosome missegregation. Unlike in wild-type cells, green fluorescent protein (GFP)-tagged Mad2 protein often accumulated near one of the poles of an elongating spindle in the gamma-tubulin mutant. We isolated novel mad2 mutants that were defective in arresting mitotic progression upon gross perturbation of the spindle formation but remained functional for the viability of the gamma-tubulin mutant. Further, the mad2 mutations did not appreciably destabilize minichromosomes in unperturbed mitoses. When overexpressed ectopically, these mutant Mad2 proteins sequestered wild-type Mad2, preventing its function in mitotic checkpoint arrest, but not in minichromosome stability. These results indicated that the Mad2 functions required for checkpoint arrest and chromosome stability in unperturbed mitosis are genetically discernible. Immunoprecipitation studies demonstrated that GFP-fused mutant Mad2 proteins formed a Mad1-containing complex with altered stability compared to that formed with wild-type Mad2, providing clues to the novel mad2 mutant phenotype.     

Molecular cloning and sequence analysis of mutant alleles of the fission yeast cdc2 protein kinase gene: Implications for cdc2+ protein structure and function

Summary The cdc2 ⁺ gene function plays a central role in the control of the mitotic cell cycle of the fission yeast Schizosaccharomyces pombe. Recessive temperature-sensitive mutations in the cdc2 gene cause cell cycle arrest when shifted to the restrictive temperature, while a second class of mutations within the cdc2 gene causes a premature advancement into mitosis. Previously the cdc2 ⁺ gene has been cloned and has been shown to encode a 34 kDa phosphoprotein with in vitro protein kinase activity. Here we describe the cloning of 11 mutant alleles of the cdc2 gene using two simple methods, one of which is presented here for the first time. We have sequenced these alleles and find a variety of single amino acid substitutions mapping throughtout the cdc2 protein. Analysis of these mutations has identified a number of regions within the cdc2 protein that are important for cdc2 ⁺ activity and regulation. These include regions which may be involved in the interaction of the cdc2 ⁺ gene product with the proteins encoded by the wee1 ⁺, cdc13 ⁺ and suc1 ⁺ genes.     

Five novel elements involved in the regulation of mitosis in fission yeast

Summary Five new elements of the mitotic control in the fission yeast Schizosaccharomyces pombe were isolated from gene libraries as multicopy suppressors of the conditional lethal phenotype of win1-1 weel ^ts cdc25^ts triple mutant strains. These genes were designated wisl ⁺ –wis5⁺for win suppressing, and do not correspond to winl ⁺ or any of the previously characterised mitotic control genes. None of the wis genes is capable of suppressing the cdc phenotype of cdc25 ^ts strains, suggesting that their effect is not simply to reverse the effect of loss of cdc25 function. wisl ⁺ has been previously reported to encode a putative serine/threonine protein kinase that acts as a dosage-dependent inducer of mitosis. wis4 ⁺ appears to be a specific suppressor of the winl-1 mutation. wis2 ⁺ and wis3 ⁺ are capable of suppressing a wide range of cdc phenotypes arising from the combination of various mutations with wee1 ^ts and cdc25 ^ts, suggesting that the wis2 ⁺ and wis3 ⁺ products may interact with elements central to the mitotic control.     

Novel alleles ofcdc13 andcdc2 isolated as suppressors of mitotic catastrophe inSchizosaccharomyces pombe

Cell cycle control in the fission yeastSchizosaccharomyces pombe involves interplay amongst a number of regulatory molecules, including thecdc2, cdc13, cdc25, weel, andmik1 gene products. Cdc2, Cdc13, and Cdc25 act as positive regulators of cell cycle progression at the G2/M boundary, while Wee1 and Mik1 play a negative regulatory role. Here, we have screened for suppressors of the lethal premature entry into mitosis, termed mitotic catastrophe, which results from simultaneous loss of function of both Wee1 and Mik1. Through such a screen, we hoped to identify additional components of the cell cycle regulatory network, and/or G2/M-specific substrates of Cdc2. Although we did not identify such molecules, we isolated a number of alleles of bothcdc2 andcdc13, including a novel wee allele ofcdc2, cdc2-5w. Here, we characterizecdc2-5w and two alleles ofcdc13, which have implications for the understanding of details of the interactions amongst Cdc2, Cdc13, and Wee1.     

A Drosophila gene encoding a DEAD box RNA helicase can suppress loss of wee1/mik1 function in Schizosaccharomyces pombe

We describe a screen to isolate cDNAs encoding Drosophila mitosis inhibitors capable of suppressing the mitotic catastrophe phenotype resulting in Schizosaccharomyces pombe from the combination of the weel-50 mutation with either a deletion allele of mil1, or with overexpression of cdc25 ⁺. One plasmid was isolated which could suppress the temperature sensitive lethality of both these strains. The cDNA in this plasmid encodes a protein highly homologous to the DEAD-box family of ATP-dependent RNA helicases, rather than to protein kinases as might be expected. It is possible that the RNA helicase described here may regulate entry into mitosis by down regulating the expression of other genes whose activity may be rate-limiting for entry into mitosis.     

The role ofSaccharomyces cerevisiae Cdc40p in DNA replication and mitotic spindle formation and/or maintenance

Successful progression through the cell cycle requires the coupling of mitotic spindle formation to DNA replication. In this report we present evidence suggesting that, inSaccharomyces cerevisiae, theCDC40 gene product is required to regulate both DNA replication and mitotic spindle formation. The deduced amino acid sequence ofCDC40 (455 amino acids) contains four copies of a -transducin-like repeat. Cdc40p is essential only at elevated temperatures, as a complete deletion or a truncated protein (deletion of the C-terminal 217 amino acids in thecdc40-1 allele) results in normal vegetative growth at 23°C, and cell cycle arrest at 36°C. In the mitotic cell cycle Cdc40p is apparently required for at least two steps: (1) for entry into S phase (neither DNA synthesis, nor mitotic spindle formation occurs at 36°C and (2) for completion of S-phase (cdc40::LEU2 cells cannot complete the cell cycle when returned to the permissive temperature in the presence of hydroxyurea). The role of Cdc40p as a regulatory protein linking DNA synthesis, spindle assembly/maintenance, and maturation promoting factor (MPF) activity is discussed.     

Chromator is required for proper microtubule spindle formation and mitosis in Drosophila

The chromodomain protein, Chromator, has been shown to have multiple functions that include regulation of chromatin structure as well as coordination of muscle remodeling during metamorphosis depending on the developmental context. In this study we show that mitotic neuroblasts from brain squash preparations from larvae heteroallelic for the two Chromator loss-of-function alleles Chro⁷¹ and Chro⁶¹² have severe microtubule spindle and chromosome segregation defects that were associated with a reduction in brain size. The microtubule spindles formed were incomplete, unfocused, and/or without clear spindle poles and at anaphase chromosomes were lagging and scattered. Time-lapse analysis of mitosis in S2 cells depleted of Chromator by RNAi treatment suggested that the lagging and scattered chromosome phenotypes were caused by incomplete alignment of chromosomes at the metaphase plate, possibly due to a defective spindle-assembly checkpoint, as well as of frayed and unstable microtubule spindles during anaphase. Expression of full-length Chromator transgenes under endogenous promoter control restored both microtubule spindle morphology as well as brain size strongly indicating that the observed mutant defects were directly attributable to lack of Chromator function.     

The genomic instability of yeast cdc6-1/cdc6-1 mutants involves chromosome structure and recombination

When diploid cells of Saccharomyces cerevisiae homozygous for the temperature-sensitive cell division cycle mutation cdc6-1 are grown at a semipermissive temperature they exhibit elevated genomic instability, as indicated by enhanced mitotic gene conversion, mitotic intergenic recombination, chromosomal loss, chromosomal gain, and chromosomal rearrangements. Employing quantitative Southern analysis of chromosomes separated by transverse alternating field gel electrophoresis (TAFE), we have demonstrated that 2N-1 cells monosomic for chromosome VII, owing to the cdc6-1 defect, show slow growth and subsequently yield 2N variants that grow at a normal rate in association with restitution of disomy for chromosome VII. Analysis of TAFE gels also demonstrates that cdc6-1/cdc6-1 diploids give rise to aberrant chromosomes of novel lengths. We propose an explanation for the genomic instability induced by the cdc6-1 mutation, which suggests that hyper-recombination, chromosomal loss, chromosomal gain and chromosomal rearrangements reflect aberrant mitotic division by cdc6-1/cdc6-1 cells containing chromosomes that have not replicated fully.     

A novel yeast mutant that is defective in regulation of the Anaphase-Promoting Complex by the spindle damage checkpoint

The accurate segregation of sister chromatids at the metaphase to anaphase transition in Saccharomyces cerevisiae is regulated by the activity of the anaphase-promoting complex or cyclosome (APC/C). In the event of spindle damage or monopolar spindle attachment, the spindle checkpoint is activated and inhibits APC/C activity towards the anaphase inhibitor Pds1p, resulting in a cell cycle arrest at metaphase. We have identified a novel allele of a gene for an APC/C subunit, cdc16-183 , in S. cerevisiae. cdc16-183 mutants arrest at metaphase at 37°C, and are supersensitive to the spindle-damaging agent nocodazole, which activates the spindle checkpoint, at lower temperatures. This supersensitivity to nocodazole cannot be explained by impairment of the spindle checkpoint pathway, as cells respond normally to spindle damage with a stable metaphase arrest and high levels of Pds1p. Despite showing metaphase arrest at G2/M at 37°C, cdc16-183 mutants are able to perform tested G1 functions normally at this temperature. This is the first demonstration that a mutation in a core APC/C subunit can result in a MAD2-dependent arrest at the restrictive temperature. Our results suggest that the cdc16-183 mutant may have a novel APC/C defect(s) that mimics or activates the spindle checkpoint pathway.Communicated by C. P. Hollenberg     

Cold-sensitive mutants of p34cdc2 that suppress a mitotic catastrophe phenotype in fission yeast.

Summary The p34^cdc2 protein kinase plays a central role in the regulation of the eukaryotic cell cycle, being required both in late G1 for the commitment to S-phase and in late G2 for the initiation of mitosis. p34^cdc2 also determines the precise timing of entry into mitosis in fission yeast, where a number of gene produts that regulate p34^cdc2 activity have been identified and characterised. To investigate further the mitotic role of p34^cdc2 in this organism we have isolated new cold-sensitive p34^cdc2 mutants. These are defective only in their G2 function and are extragenic suppressors of the lethal premature entry into mitosis brought about by mutating the mitotic inhibitor p107^wee1 and overproducing the mitotic activator p80^cdc25. One of the mutant proteins p34^cdc2-E8 is only functional in the absence of p107^wee1, and all the mutant strains have reduced histone H1 kinase activity in vitro. Each mutant allele has been cloned and sequenced, and the lesions responsible for the cold-sensitive phenotypes identified. All the mutations were found to map to regions that are conserved between the fission yeast p34^cdc2 and functional homologues from higher eukaryotes.     

Plc1p is required for proper chromatin structure and activity of the kinetochore in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> by facilitating recruitment of the RSC complex

High-fidelity chromosome segregation during mitosis requires kinetochores, protein complexes that assemble on centromeric DNA and mediate chromosome attachment to spindle microtubules. In budding yeast, phosphoinositide-specific phospholipase C (Plc1p encoded by PLC1 gene) is important for function of kinetochores. Deletion of PLC1 results in alterations in chromatin structure of centromeres, reduced binding of microtubules to minichromosomes, and a higher frequency of chromosome loss. The mechanism of Plc1p’s involvement in kinetochore activity was not initially obvious; however, a testable hypothesis emerged with the discovery of the role of inositol polyphosphates (InsPs), produced by a Plc1p-dependent pathway, in the regulation of chromatin-remodeling complexes. In addition, the remodels structure of chromatin (RSC) chromatin-remodeling complex was found to associate with kinetochores and to affect centromeric chromatin structure. We report here that Plc1p and InsPs are required for recruitment of the RSC complex to kinetochores, which is important for establishing proper chromatin structure of centromeres and centromere proximal regions. Mutations in PLC1 and components of the RSC complex exhibit strong genetic interactions and display synthetic growth defect, altered nuclear morphology, and higher frequency of minichromosome loss. The results thus provide a mechanistic explanation for the previously elusive role of Plc1p and InsPs in kinetochore function. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Functional analysis of theDrosophila CDC2 Dm gene in fission yeast

Thecdc2 ⁺ gene product (p34^cdc2) is a protein kinase that regulates entry into mitosis in all eukaryotic cells. The role that p34^cdc2 plays in the cell cycle has been extensively investigated in a number of organisms, including the fission yeastSchizosaccharomyces pombe. To study the degree of functional conservation among evolutionarily distant p34^cdc2 proteins, we have constructed aS. pombe strain in which the yeastcdc2 ⁺ gene has been replaced by itsDrosophila homologue CDC2Dm (theCDC2Dm strain). ThisCDC2Dm S. pombe strain is viable, capable of mating and producing four viable meiotic products, indicating that the fly p34^CDC2Dm recognizes all the essentialS. pombe cdc2 ⁺ substrates, and that it is recognized by cyclin partners and other elements required for its activity. The p34^CDC2Dm protein yields a lethal phenotype in combination with the mutant B-type cyclin p56^cdc13-117, suggesting that thisS. pombe cyclin might interact less efficiently with theDrosophila protein than with its native p34^cdc2 counterpart. ThisCDC2Dm strain also responds to nutritional starvation and to incomplete DNA synthesis, indicating that proteins involved in these signal transduction pathways, interact properly with p34^CDC2Dm (and/or that p34^cdc2-independent pathways are used). TheCDC2Dm gene produces a ‘wee’ phenotype, and it is largely insensitive to the action of theS. pombe weel ⁺ mitotic inhibitor, suggesting thatDrosophila weel ⁺ homologue might not be functionally conserved. ThisCDC2Dm strain is hypersensitive to UV irradiation, to the same degree asweel-deficient mutants. A strain which co-expresses theDrosophila and yeastcdc2⁺ genes shows a dominantwee phenotype, but displays a wild-type sensitivity to UV irradiation, suggesting that p34^cdc2 triggers mitosis and influences the UV sensitivity by independent mechanisms. Communicated by B. J. Kilbey     

The behaviour of kinetochore microtubules during meiosis in the fungusSaprolegnia

Summary InSaprolegnia, kinetochore microtubules persist throughout the mitotic nuclear cycle but, whilst present at leptotene, they disappear coincidently with the formation of synaptonemal complexes at pachytene and reform at metaphase I. In some other fungi chromosomal segregation is random in meiosis and non-random in mitosis. The attachment of chromosomes to persistent kinetochore microtubules in mitosis, but not meiosis, inSaprolegnia provides a plausible explanation for such behaviour. At metaphase I each bivalent is connected to the spindle by 2 laterally paired kinetochore microtubules whereas at metaphase II (as in mitosis) each univalent bears only one kinetochore microtubule, thus showing that all kinetochores are fully active at all stages of meiosis.     

Asymmetric distribution of mitochondria and of spindle microtubules in opposite directions in differential mitosis of germ line cells in Acricotopus

Additional chromosomes present only in the germ line are a specific feature of the Orthocladiinae, a subfamily of the Chironomidae. During the complex chromosome cycle in the orthocladiid Acricotopus lucidus, about half of the germ-line-limited chromosomes (Ks) are eliminated in the first division of the primary germ cells. Following normal gonial mitoses, the reduction in the number of Ks is compensated for, in the last mitosis prior to meiosis, by a monopolar movement of the unseparated Ks, while the somatic chromosomes (Ss) segregate equally. This differential mitosis produces daughter cells with different chromosome constitutions and diverse developmental fates. A preferential segregation of mitochondria occurs to one pole associated with an asymmetric formation of the mitotic spindle. This has been detected in living gonial cells in both sexes by using MitoTracker probes and fluorochrome-labelled paclitaxel (taxol). In males, the resulting unequal partitioning of mitochondria to the daughter cells is equalised by the transport of mitochondria through a permanent cytoplasmic bridge from the aberrant spermatocyte to the primary spermatocyte. This asymmetry in the distribution and in the segregation of cytoplasmic components in differential gonial mitosis in Acricotopus may be involved in the process of cell-fate determination. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorised users.     

Functional characteristics of the individual genomic condensin binding sites of Saccharomyces cerevisiae using minichromosome mitotic segregation stability model

Proper chromatin compaction in mitosis (condensation) is required for equal chromosome distribution and precise genetic information inheritance. Protein complex named condensin is responsible for the mitotic condensation, it also individualizes chromosomes, and ensures chromatin separation between sister chromatids in mitosis as well as proper mitotic spindle tension. Mitotic condensin function depends on recognition of the specific binding sites on the chromosome. Mechanism of condensin binding on the individual sites of the mitotic chromosomes, as well as molecular anatomy of these sites remains to be unclear. Even less known is how condensin binding on the individual sites helps separating chromosomes in anaphase. In current paper using minichromosome test, we analyze seven individual condensin binding sites in Saccharomyces cerevisiae found in previous all-genome CHIP on CHIP screening in our lab. This approach allowed us to find out what was the individual contribution of condensin binding sites in securing mitotic stability of the minichromosomes.     

Identification of Trans-Acting Genes Necessary for Centromere Function in Drosophila Melanogaster Using Centromere-Defective Minichromosomes

Deletions in the Drosophila minichromosome Dp1187 were used to investigate the genetic interactions of trans-acting genes with the centromere. Mutations in several genes known to have a role in chromosome inheritance were shown to have dominant effects on the stability of minichromosomes with partially defective centromeres. Heterozygous mutations in the ncd and klp3A kinesin-like protein genes strongly reduced the transmission of minichromosomes missing portions of the genetically defined centromere, but had little effect on the transmission of minichromosomes with intact centromeres. Using this approach, ncd and klp3A were shown to require only the centromeric region of the chromosome for their roles in chromosome segregation. Increased gene dosage also affected minichromosome transmission and was used to demonstrate that the nod kinesin-like protein gene interacts genetically with the centromere, in addition to interacting with extracentromeric regions as demonstrated previously. The results presented in this study strongly suggest that dominant genetic interactions between mutations and centromere-defective minichromosomes could be used effectively to identify novel genes necessary for centromere function.