Isolation of a Schizosaccharomyces pombe rad21ts Mutant That Is Aberrant in Chromosome Segregation, Microtubule Function, DNA Repair and Sensitive to Hydroxyurea: Possible Involvement of Rad21 in Ubiquitin-Mediated Proteolysis

Isolation of a Schizosaccharomyces pombe rad21^ts Mutant That Is Aberrant in Chromosome Segregation, Microtubule Function, DNA Repair and Sensitive to Hydroxyurea: Possible Involvement of Rad21 in Ubiquitin-Mediated Proteolysis

Kazuo Tatebayashi^a, Jun-ichi Kato^a, and Hideo Ikeda^a
^a Department of Molecular Biology, Institute of Medical Science, University of Tokyo, P.O. Takanawa, Tokyo 108, Japan

Corresponding author: Hideo Ikeda, Department of Molecular Biology, Institute of Medical Science, University of Tokyo, 4-6-1, Shirokanedai Minato-ku, P.O. Takanawa, Tokyo 108, Japan, ike{at}hgc.ims.u-tokyo.ac.jp (E-mail).

Communicating editor: F. WINSTON

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

The fission yeast DNA repair gene rad21⁺ is essential for cellgrowth. To investigate the function essential for cell proliferation,we have isolated a temperature-sensitive mutant of the rad21⁺gene. The mutant, rad21-K1, showed abnormal mitosis at the nonpermissivetemperature. Some cells contained abnormal nuclear structures,such as condensed chromosomes with short spindles, or chromosomesstretched or unequally separated by elongating spindles. Othercells exhibited the displaced nucleus or a cut-like phenotype.Similar abnormalities were observed when the Rad21 protein wasdepleted from cells. We therefore concluded that Rad21 is essentialfor proper segregation of chromosomes. Moreover, the rad21-K1mutant is sensitive not only to UV and ${gamma}$ -ray irradiation butto thiabendazole and hydroxyurea, indicating that Rad21 playsimportant roles in microtubule function, DNA repair, and S phasefunction. The relation to the microtubule function was furtherconfirmed by the fact that rad21⁺ genetically interacts withtubulin genes, nda2⁺ and nda3 ⁺. Finally, the growth of therad21-K1 mutant was inhibited at the permissive temperatureby introduction of another mutation in the cut9 ⁺ gene, codingfor a component of the 20S cyclosome/anaphase promoting complex,which is involved in ubiquitin-mediated proteolysis. The resultssuggest that these diverse functions of Rad21 may be facilitatedthrough ubiquitin-mediated proteolysis.

ADNA double-strand break repair system is important for cellproliferation because DNA is often damaged during mitosis by ${gamma}$ rays and other DNA-damaging agents. DNA double-strand breaksare usually repaired by homologous and nonhomologous recombination(MILNE et al. 1996 ). A checkpoint control system, which inhibitscell cycle progression when DNA is damaged, is also importantfor DNA repair (HARTWELL and WEINERT 1989 ). These DNA repairand checkpoint control systems have been genetically investigatedusing a number of radiation-sensitive, rad, mutants in yeast.

More than 20 rad genes have been identified in fission yeast,and those are divided into three groups based on the sensitivityto UV and ${gamma}$ rays (PHIPPS et al. 1985 ). The rad genes, mutationsin which confer sensitivity to both UV and ${gamma}$ rays, are designatedas the group 1 genes and the genes responsible for sensitivityto UV but not to ${gamma}$ rays are named as the group 2 genes. The group3 genes are the genes for sensitivity to ${gamma}$ rays rather than UVirradiation. The rad21⁺ gene is a group 3 gene. The Rad21 proteinis a nuclear protein that is involved in DNA double-strand breakrepair and that is phosphorylated during cell cycle (BIRKENBIHLand SUBRAMANI 1995 ). A unique feature of the rad21⁺ gene isthat its function is essential for vegetative growth of cells(BIRKENBIHL and SUBRAMANI 1992 ). The depletion of Rad21 proteinfrom cells was reported to result in disturbance of nuclearorganization caused by aberrant mitosis (BIRKENBIHL and SUBRAMANI1995 ).

In fission yeast, a number of conditionally lethal mutants thatexhibit aberrant or defective mitosis at the restrictive temperaturehave been isolated. Among them, there is a class of temperature-sensitive(TS) mutants, the cut [c ell u ntimely t orn (HIRANO et al.1986 ; SAMEJIMA et al. 1993 )] mutants, in which the coordinationof mitotic processes is disturbed at the restrictive temperature;thus, cell division takes place in the absence of nuclear division,leading to bisection of a nucleus with a septum or uneven separationof chromosomes. This cut phenotype is also caused by the mutationsin the top2⁺ gene encoding a type II topoisomerase (UEMURA andYANAGIDA 1986 ). Recent genetic studies have unmasked the rolesof some cut genes. The cut7⁺ gene encodes a kinesin-like proteinand is thought to play a crucial role as a mitotic motor inmitosis (HAGAN and YANAGIDA 1990 ). The cut5⁺ gene is requiredfor initiation and/or elongation of DNA replication and alsofor the DNA replication checkpoint (SAKA and YANAGIDA 1993 ; SAKA et al. 1994B ).

Recently the cut9 ⁺ gene product was found to be one of thekey proteins for the transition from metaphase to anaphase duringmitosis (SAMEJIMA and YANAGIDA 1994B ). The cut9 mutant showedmetaphase arrest at the restrictive temperature and, ultimately,a cut phenotype. The Cut9 protein is homologous to the Cdc16protein of budding yeast. The Cdc16 protein is required forsister chromatid separation and B-type cyclin proteolysis (LAMBet al. 1994 ; IRNIGER et al. 1995 ). The Cdc16 homolog of Xenopuslaevis is a component of the 20S cyclosome (APC), which is aubiquitin ligase required for destruction of mitotic cyclinand initiation of anaphase (KING et al. 1995 ). The Cut9 proteinof fission yeast is also reported to be a component of 20S cyclosome(YAMASHITA et al. 1996 ). The target of the ubiquitin-mediatedproteolysis for the metaphase-anaphase transition is suggestedto be the Cut2 protein in fission yeast (FUNABIKI et al. 1996) and the Pds1 protein in budding yeast (YAMAMOTO et al. 1996), and Cut9 is reported to be essential for Cut2 degradation(FUNABIKI et al. 1996 ).

In this work, to investigate the function of the fission yeastrad21⁺ gene, we isolated a temperature-sensitive mutant of thegene. This mutant was defective in chromosome segregation becauseit exhibits the cut-like phenotype at the restrictive temperature,and it is sensitive to DNA-damaging agents and inhibitors oftubulin assembly and DNA replication at the permissive temperature.Also the rad21^ts mutation affected growth of the strains harboringmutations in the tubulin gene nda2⁺ or the cut9 ⁺ gene. Theseresults indicate that the Rad21 protein is essential for chromosomesegregation and suggest that it is involved in microtubule function,DNA repair, and S-phase function via the ubiquitin-mediatedproteolysis.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Yeast strains, media and genetic methods:
JY 741 (h⁺ ade6-M216 leu1-32 ura4-D18) was used as a wild-typestrain. nda2-KM52, nda3-KM311, cut9-665, and other cut mutantswere isolated previously (TODA et al. 1983 ; HIRANO et al.1986 ). The strains used in this study have the same geneticbackground as JY 741 except the relevant mutations and the uracilauxotrophy. Media used for culture are Y ES (0.5% yeast extract;3% glucose; supplemented with adenine, leucine, and uracil at100 µg/ml) and EMM (minimal medium). For the synchronizationof the cells at G1 phase, nitrogen source (NH₄Cl) was omittedfrom EMM. Thiamine was added to EMM at a final concentrationof 16 µM for the transcriptional repression of Rad21.Media containing 2% agar were used for plating. Standard geneticprocedures (GUTZ et al. 1974 ; MORENO et al. 1991 ) for fissionyeast were used.

Plasmids and yeast transformation procedure:
Transformation of Schizosaccharomyces pombe was performed bythe lithium acetate method described by OKAZAKI et al. 1990. For construction of the plasmid pRn821, the open-reading frameof rad21⁺ was amplified by PCR with a set of primers, resultingin modification of the sequence around the initiation codonfrom CTTATG to the Nde I recognition sequence CATATG. The amplifiedopen reading frame was inserted into pRep81 plasmid so thatinitiation codon was located in Nde I site downstream of theweak nmt1 promoter (MAUNDRELL 1993 ). The resultant plasmid(Rn821) was used for checking the synthetic lethality betweenrad21-K1 and cut or nda2 mutants.

Isolation of the temperature-sensitive allele of rad21:
The 3.3-kb DNA fragments containing rad21⁺ was amplified byPCR method in the presence of 0.2 mM Mn⁺⁺, which significantlyreduced the fidelity of polymerization by Taq polymerase andproduced mutated gene fragments (SHIMIZU et al. 1997 ). A mixtureof the mutated rad21 fragments was cloned between Nde I andSal I sites of pUC18 plasmid, followed by insertion of the selectionmarker ura4⁺ gene in the Bgl II site located downstream of thestop codon. The resultant plasmids were digested with HindIII,located upstream of the first ATG of rad21⁺, and EcoRI withinthe pUC18 polylinker, and the pool of mutated rad21 fragmentswith the inserted ura4⁺ gene was introduced into JY 741 cells.Stable Ura⁺ transformants were isolated as recombinants at 25°,in most of which the chromosomal copy of the rad21⁺ gene wasreplaced with the mutated one by homologous recombination (Figure1). TS mutants, which cannot grow on Y ES plates at 36°,were selected among the recombinants. They were back-crossedwith a wild-type strain and used for further analyses.

View larger version (21K):
[in this window]
[in a new window]

Figure 1. —Isolation of temperature-sensitive alleles of rad21-K1. A pool of mutated rad21 DNA fragments with the selection marker ura4⁺ gene was introduced into the ${Delta}$ ura4 strain. The chromosomal rad21⁺ gene is replaced with the mutated one by homologous recombination. The selection marker ura4⁺ gene is inserted between the rad21 open-reading frame (striped box) and its downstream region (open box). An asterisk (*) indicates the postulated mutation site; H, HindIII; B, Bgl II; C, Cla I.

Fluorescence microscopy:
4',6-diamidino-2-phenylindole (DAPI) staining of the cells wasdone as described (ADACHI and YANAGIDA 1989 ). Immunofluorescencemicroscopy using antitubulin antibody YOL1/34 (Sera-lab, Sussex,UK) as the primary antibody and a rhodamine-conjugated goatanti-rat IgG (Immunotech S. A., Marseille, France) as the secondaryantibody was described by HAGAN and HYAMS 1988 .

FACScan Analysis:
A Becton Dickinson (San Jose, CA) FACScan was used to estimatethe DNA content. Procedures for cell preparation were as follows.Cells were collected, washed with distilled water, and resuspendedin 0.3 ml of distilled water. Ethanol was added to a final concentrationof 70%, and cells were stored at 4° for at least 12 hrs.The cells were washed with buffer A [200 mM Tris-HCl, 20 mMEDTA (pH 7.0)], and resuspended in the same buffer. After sonicationof the cell suspensions, RNase A was added to a final concentrationof 0.2 mg/ml. Following a 4-hr incubation at 37°, propidiumiodide (Sigma Chemical Co., St. Louis, MO) was added to a finalconcentration of 10 µg/ml. The resulting cell suspensionswere analyzed.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Isolation of a temperature-sensitive mutant of the rad21 gene:
To isolate temperature-sensitive mutants of the rad21⁺ gene,we did localized mutagenesis of the gene using PCR. A mixtureof randomly mutagenized rad21 DNA fragments was cloned intopUC18 plasmid and inserted by the selection marker ura4⁺ geneat the position just downstream of the stop codon. The constructedlibrary was linearized by restriction digestion and then introducedinto a ${Delta}$ ura4 strain for replacement of the chromosomal rad21⁺gene with the mutated one by homologous recombination (Figure1). Among the Ura⁺ transformants, stable Ura⁺ recombinants wereselected at 25°, and ts mutants, which could not grow athigh temperature (36°) on a Y ES plate, were identified.One TS mutant (rad21-K1) was isolated among 21 stable Ura⁺ recombinants.It was confirmed by Southern blotting that the chromosomal rad21⁺gene has been replaced by the mutant one with the ura4⁺ geneas a single copy and that temperature sensitivity is linkedto the ura4⁺ marker. As shown in Figure 2A, the rad21-K1 mutantcontinued to grow for about two rounds of cell cycle, and thecell viability was gradually decreased at 36° to about 5%after 6 hrs. The rad21-K1 is also sensitive to both UV and ${gamma}$ -rayirradiation at 25° (Figure 2B). The rad21⁺ plasmid correctedboth ts growth and UV and ${gamma}$ -ray sensitivity, indicating thatboth phenotypes were caused by the mutation in the rad21⁺ gene(data not shown).

View larger version (14K):
[in this window]
[in a new window]

Figure 2. —Growth rate of the rad21-K1 mutant and its sensitivity to radiation. (A) Cell growth and viability of the rad21-K1 cells at 36°. Wild-type and the rad21-K1 cells grown at 25° were shifted to 36°. Number of cells in each culture was counted under microscope. Open circle indicates wild-type; filled circle, rad21-K1. The viability of rad21-K1 was measured by plating (broken lines). (B) Survival of the rad21-K1 cells after UV (top panel) or ${gamma}$ -ray irradiation (bottom panel). Survival rates were measured by exposing serial dilutions of exponentially growing cells to various doses of UV or ${gamma}$ ray. Colonies were counted after 4–5 days at 25°. Open circle indicates wild-type; filled circle, rad21-K1.

Mitotic defect in the rad21-K1 mutant:
We studied nuclear morphology and spindle structure of the rad21-K1mutant after shift-up to 36° (Figure 3). When the mutantwas incubated at 25°, the majority of the cells exhibitedan interphase cell morphology and had a single nucleus withthe hemispherical chromatin region, as observed in the wild-typestrain incubated at 25° or 36° (data not shown). Aftershift-up to 36°, however, the interphase cells graduallydecreased, and cells with abnormal chromosome structures appeared.Some cells had condensed chromosomes and short spindles, reminiscentof cells arrested at metaphase. Other cells had aberrant earlyor midanaphase chromosomes. Among this type of cells, therewere cells that contained the fibrous chromosomes stretchedby an elongating mitotic spindle, and cells with the chromosomesscattered along the cell axis. The scattered chromosomes oftenformed three blocks of nuclear material, which may be threepairs of unsegregated sister chromatids, suggesting that thesister chromatids did not appear to be separated completely.There were also cells with unevenly segregated chromosomes,cells with the displaced nucleus, and cells showing the cut-likephenotype, suggesting that septation occurred without normalseparation of chromosomes. The results indicated that most ofthe cells exhibited the defects of precise segregation of thechromosomes.

View larger version (48K):
[in this window]
[in a new window]

Figure 3. —Nuclear morphology of the rad21-K1 cells at 36°. (A) Frequency of the cells displaying aberrant chromatin structures. Cells grown at 25° were transferred to 36°. Cells were collected, fixed, and stained using DAPI or antitubulin antibody. Frequency of each type of cells was indicated. Filled circle indicates the interphase chromatin; filled square, the condensed, stretched, or unequally segregated chromosomes; open circle, the cut-like phenotype or the displaced nucleus; open square, the fragmented or less-stained chromosomes. (B) Nuclear and spindle structures of rad21-K1 incubated at 36° for 4 hr. The rad21-K1 cells incubated at 36° for 4 hr were analyzed by immnofluorescence using antitubulin antibody YOL1/34 and DAPI staining. Many types of aberrant mitotic cells were observed: 1. the condensed chromosomes; 2. the scattered chromosomes; 3. the unequally segregated chromosomes; 4. the stretched chromosomes; 5. the displaced chromosomes to one end of the cell; 6. the cut-like phenotype.

We constructed a rad21 disruptant in the presence of a plasmid,Rn821, which carries the rad21⁺ gene in the downstream regionof the Rep81 promoter, a weak nmt1 promoter (MAUNDRELL 1993), on a thiamine-free plate at 30°. When the Rad21 proteinwas depleted by repressing the Rep81 promoter with incubationin the presence of thiamine, there appeared aberrant mitoticcells similar to those observed in the ts mutant at the nonpermissivetemperature (data not shown). Therefore, we concluded that therad21⁺ gene product is required for normal progression of mitosis.

Involvement of the Rad21 protein in the microtubule function:
In many of the rad21-K1 mutant cells, a mitotic spindle wasnot fully elongated at the restrictive temperature; therefore,we supposed that the mutant might be defective in the microtubulefunction. First, we examined sensitivity to an antimicrotubuleagent, thiabendazole (TBZ). As shown in Figure 4A, the rad21-K1mutant was more sensitive to TBZ at 25° than the isogenicrad21⁺ strain at a concentration of 10 µg, although thesensitivity was not so severe as that of the ${alpha}$ -tubulin mutantnda2 (data not shown).

View larger version (51K):
[in this window]
[in a new window]

Figure 4. —Involvement of Rad21 in the microtubule function. (A) A semi-quantitative analysis of TBZ sensitivity of the rad21-K1 cells. Serial dilutions of exponentially growing cells at 25° by 10-fold were spotted on Y ES with (bottom panel) or without (top panel) thiabendazole (10 µg). Plates were incubated at 25° for 3 days. (B) Cell shape and nuclear structure of the rad21-K1 nda3-KM311 double mutant. The cells grown at 25° were collected and stained with DAPI. The stained cells were photographed with a fluorescence microscope with phase-contrast optics. (a) rad21-K1 nda3-KM311 (b) nda3-KM311 (c) rad21-K1. (C) Effect of the depletion of wild-type Rad21 in the rad21-K1 nda2-KM52 double mutant. The yeast strains (wild-type, rad21-K1, nda2-KM52, and rad21-K1 nda2-KM52) harboring Rn821 were streaked onto EMM with or without thiamine (16 µM) at 30°.

Next, to study the genetic interaction between rad21 and mutationsin tubulin genes [nda2 ${alpha}$ 1-tubulin mutant (TODA et al. 1984 )and nda3 ß-tubulin mutant (HIRAOKA et al. 1984 )], wetried to construct the double mutants. A rad21-K1 nda3-KM311double mutant was constructed by crossing the TS rad21-K1 mutantand the cold-sensitive nda3-KM311 mutant at 30°. The resultingdouble mutant grew more slowly than each of the single mutantsat 25°. Furthermore, observation of cell shape of the doublemutant revealed a large number of branched, swollen, or elongatedcells at 25° (Figure 4B), while the nda3-KM311 single mutantdid not exhibit a similar phenotype at 25° but 20° asreported previously (TODA et al. 1983 ). These results indicatedthat the rad21-K1 mutation enhanced the defect of the nda3-KM311mutation.

With regard to the nda2⁺ gene, we failed to construct the rad21nda2 double mutant by crossing the rad21-K1 and the nda2-KM52single mutants at 30°. But the double mutant was obtainedon a thiamine-free plate at 30° in the presence of the rad21⁺plasmid, Rn821, which we described earlier. The growth of therad21-K1 nda2-KM52 double mutant was severely inhibited on thethiamine-containing plates, on which the expression of the rad21⁺gene was repressed at both 28° and 30°, but not on thiamine-freeplates, although the control strains carrying the same plasmid,the rad21⁺ nda2⁺ strain and either of the single mutants, grewnormally (Figure 4C). These results strongly suggested thatthe rad21-K1 nda2-KM52 double mutant was inviable. The nuclearmorphology of the rad21-K1 nda2-KM52 cells was studied afterthe Rep81 promoter was repressed by addition of 16 µMthiamine at 28°. DAPI-staining of the rad21-K1 nda2-KM52mutant revealed that aberrantly shaped or elongated cells frequentlyappeared and that many of the cells exhibited disturbed nuclearorganization (data not shown). The results on the TBZ sensitivityof the rad21-K1 mutant and genetic interaction between rad21and nda2 or nda3 mutations suggested that Rad21 is involvedin microtubule function.

Hydroxyurea sensitivity of the rad21-K1 mutant:
To ex- amine a possible involvement of Rad21 in the checkpointcontrol of DNA replication, we examined the sensitivity of therad21-K1 mutant to hydroxyurea (HU). As shown in Figure 5A,the mutant was found to be more sensitive to HU at the permissivetemperature than the isogenic rad21⁺ strain. This phenotypewas also complemented by the rad21⁺ plasmid (data not shown).We also examined the viability of the mutant after transientexposure to HU because viability of the rad3 mutant, which isdefective in the replication checkpoint system (AL-KHODAIRYand CARR 1992 ; JIMENEZ et al. 1992 ), decreases drasticallyafter incubation for 2 hr in 10 mM HU. However, viability ofthe rad21-K1 mutant was scarcely reduced and the cut-like phenotypewas not observed after incubation for 6 hr in the presence of10 mM HU (data not shown). Although the results indicated thatthe rad21-K1 mutant is sensitive to HU, the role of Rad21 inthe DNA replication checkpoint remains to be determined.

View larger version (34K):
[in this window]
[in a new window]

Figure 5. —Effects of the rad21-K1 mutation on DNA replication. (A) A semi-quantitative analysis of HU sensitivity of rad21-K1 cells. Serial dilutions of exponentially growing cells at 25° by 10-fold were spotted on Y ES with (bottom panel) or without (top panel) hydroxyurea (5 mM). Plates were incubated at 25° for 3 days. (B) FACScan analysis of the rad21-K1 mutant grown at 36°. (a) The DNA contents of the rad21-K1 cells grown asynchronously at 25° and shifted up to 36°. Cells grown at 25° were shifted to 36°, and aliquots were collected for analysis of the DNA content by a Becton-Dickinson FACScan. Left panel, wild-type (wt) cells; right panel, rad21-K1. (b) The DNA contents of the rad21-K1 cells synchronized by nitrogen starvation and incubated at 36° after release. Cells were first arrested in EMM-N lacking nitrogen source at 25° for 12–13 hr, and then shifted to 36°. After a 1-hr incubation at 36°, cells were moved to the complete medium, followed by further incubation at 36°. The DNA contents of wild-type cells (wt; left panel) and rad21-K1 cells (right panel) were estimated by FACScan.

As the rad21-K1 cells are moderately sensitive to HU, we examinedthe possibility that Rad21 might be involved in cell cycle progressionin S phase. Asynchronous cells grown at 25° were transferredto 36°, and aliquots were collected every 1 hr and analyzedby FACScan analysis (Figure 5B a). In the wild-type cells, theDNA content remained 2C for 6 hr after shift-up. The 2C peakof the rad21-K1 cells, however, became broader after shift-upto 36°. This result indicated that the rad21-K1 cells areheterogeneous in their DNA content, and it is consistent withthe observation that the rad21-K1 mutant undergoes aberrantmitosis under the restrictive temperature. In addition, becausesome populations contained the elongated cells characteristicof cell-division cycle delay at the restrictive temperature,apparent heterogeneity of the DNA content might be partiallybecause of cell shape or size. DNA contents of the synchronouscells were also examined under 36° after release from G1arrest by nitrogen starvation (Figure 5B b). In the rad21-K1mutant, the peak of 1C content moved to 2C under the restrictivetemperature as observed in the wild-type cells but, thereafter,DNA content became gradually heterogeneous as seen in the asynchronousculture. The result showed that the bulk of DNA replicationtakes place normally in the rad21-K1 mutant, although we cannotrule out the possibility that there is a deficiency in the completionof the replication in the rad21-K1 cells.

Genetic interaction of rad21 and cut9 mutations:
Because the rad21-K1 mutant showed the cut-like phenotype, itis possible that the function of the rad21-K1 gene product maybe related to those of other cut gene products. Thus we studiedthe effects of the rad21 mutation in combination with othercut mutations. The cut1-206, cut3-477, cut7-446, cut8-563, andcut9-665 mutants (HAGAN and YANAGIDA 1990 ; UZAWA et al. 1990; SAKA et al. 1994A ; SAMEJIMA and YANAGIDA 1994A ; SAMEJIMAand YANAGIDA 1994B ) were crossed with the rad21-K1 mutant carryingthe plasmid, Rn821, on thiamine-free plates. Although the cut1rad21, cut3 rad21, cut7 rad21, and cut8 rad21 double mutantsgrew on a thiamine-containing plate, the cut9 rad21 double mutantdid not form colonies on the same plate at 30° (Figure 6A).This double mutant grew on a thiamine-containing plate at 25°,but more slowly than the isogenic rad21⁺ strain.

View larger version (68K):
[in this window]
[in a new window]

Figure 6. —Phenotype of the rad21-K1 cut9-665 double mutant. (A) The rad21-K1 cut9-665 cells grown at 30°. The yeast strains (wild-type cells, rad21-K1, cut9-665, and rad21-K1 cut9-665) harboring Rn821 were streaked onto EMM with or without thiamine (16 µM) at 30°. (B) Nuclear structure of the cells in the rad21-K1 cut9-665 culture at 30°. The rad21-K1 cut9-665 cells were exponentially grown at 30° in EMM, and then thiamine was added to the culture at the final concentration of 16 µM followed by further incubation for 15 hr. The cells were collected, fixed, and stained with DAPI. Cells grown in the absence of thiamine were also shown on the right top half of the figure.

Nuclear structure of the double mutant was examined after repressionof expression of the rad21⁺ gene by addition of thiamine tothe culture at 30°. There appeared aberrant mitotic cells,that is, cells with the chromosomes segregated unevenly, cellswith scattered chromosomes, and cut-like cells and elongatedcells with fibrous chromosomes (Figure 6B). These results indicatedthat the defect of the rad21 mutant was enhanced by the cut9mutation. As described in the INTRODUCTION, because the Cut9is a component of the 20S cyclosome (a ubiquitin ligase), therad21⁺ gene product could be involved in the ubiquitin-mediatedproteolysis pathway.

DISCUSSION

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Requirement of Rad21 for chromosome segregation:
We have isolated and characterized a TS mutant of the fissionyeast rad21⁺ gene, which exhibited aberrant mitotic morphologyat the restrictive temperature. BIRKENBIHL and SUBRAMANI 1995 reported that shut-off of Rad21 expression led to dispersionof the nuclear materials, and they supposed that it was causedby aberrant mitosis. We confirmed their results and furtheradded a new insight that Rad21 is necessary for chromosome segregation.One type of the aberrant mitotic cells contained condensed chromosomeswith short spindles, which are reminiscent of the metaphase-arrestedcells. Another type of the cells had stretched, scattered, orunequally separated chromosomes along mitotic spindles, whichare perhaps caused by failure of precise chromosome segregationat early anaphase. Appearance of these cells suggested thatthe rad21-K1 mutant is deficient in the metaphase-anaphase transitionor faithful progression of anaphase. We therefore concludedthat Rad21 is necessary for chromosome segregation. However,it is not clarified yet whether Rad21 is essential for onlyM phase or several steps of cell cycle. We are currently investigatingthis point by analysis with synchronous culture of rad21-K1.Recently, we isolated TS mutants of the budding yeast RHC21gene, a homolog of rad21⁺, and found that the mutants are alsodefective in chromosome segregation (S. J. HEO, K. TATEBAYASHI,J. KATO and H. IKEDA, unpublished results). The function seemsto be conserved between the fission yeast rad21⁺ gene and thebudding yeast RHC21 gene.

Involvement of Rad21 in DNA repair, the S-phase function and the microtubule function:
Analyses with the rad21-K1 mutant showed its pleiotropic phenotypes.First, the rad21-K1 mutant is moderately sensitive to TBZ. TBZis known to bind tubulin molecules and to inhibit polymerizationof tubulin molecules. In fission yeast, TBZ-sensitive or resistantmutants have been isolated so far, and these were the mutantsof the tubulin genes, nda2⁺ or nda3⁺ (UMESONO et al. 1983 ).Moreover, the rad21-K1 mutation inhibits the growth of the nda2mutant and enhances the effect of the nda3 mutation. These resultsindicated that the Rad21 protein is involved in the microtubulefunction. There are two possible roles of Rad21 in microtubulefunction. Rad21 may be involved in maintenance of microtubulestructures or the polymerization process of the tubulin molecules,because the microtubule structures are disrupted by TBZ andtheir stability is affected by the tubulin mutations. The microtubulestructures observed by tubulin staining do not seem to be aberrantin the rad21-K1 cells at the restrictive temperature, but furtheranalysis will be needed to clear this point. Alternatively,the rad21⁺ gene product may be involved in spindle assemblycheckpoint. Several genes participated in the spindle assemblycheckpoint, which ensures that cells execute mitosis only aftercompletion of spindle formation, have been identified in otherorganisms (HOYT et al. 1991 ; LI and MURRAY 1991 ; CROSS etal. 1995 ). Using this checkpoint system, cells arrest at G2/Mphase when spindles are not assembled. In the mutants defectivein this system, mitosis takes place even when spindles are notassembled; thus, chromosome loss occurs frequently.

Secondly, the rad21-K1 mutant was sensitive to UV, ${gamma}$ -ray irradiation,and HU. The double mutant carrying the rad21-K1 mutation anda TS mutation of the cdc17⁺ gene, which codes for DNA ligase,cannot grow at 30° (K. TATEBAYASHI, J. KATO and H. IKEDA,unpublished results). Radiation- or HU-sensitivity and syntheticlethality with the cdc17 mutation has also been shown in severalcheckpoint mutants (AL-KHODAIRY and CARR 1992 ). Functions ofRad21 in DNA repair and S-phase progression has not yet beenclarified, but it is possible that the rad21-K1 mutant may bedefective in mitotic checkpoint control systems, which preventspremature mitosis before completion of DNA replication, DNArepair, and the spindle assembly. The PDS1 gene has been identifiedin budding yeast, and its product is thought to be a globalnegative regulator of cell cycle progression (YAMAMOTO et al.1996 ). The pds1 mutant does not arrest at G2/M after irradiationto ${gamma}$ ray or exposure to an antimicrotubule drug, Nocodazole,indicating that the mitotic checkpoint is defective. Furthermore,degradation of the Pds1 protein is required for metaphase-anaphasetransition. The Rad21 protein may play roles in regulation ofvarious checkpoint systems and in mitosis, as the Pds1 proteindoes. Recently, homologues of Aspergillus nidulans bimE geneproduct in Schizosaccharomyces pombe (YAMASHITA et al. 1996), Saccharomyces cerevisiae (ZACHARIAE et al. 1996 ), and Xenopuslaevis (PETERS et al. 1996 ) were shown to be components of20S cyclosome. The bimE gene is required not only for initiationof anaphase but also for mitotic checkpoint control (OSMANIet al. 1988 ; OSMANI et al. 1991 ; JAMES et al. 1995 ). Theseresults suggest that 20S cyclosome plays a regulatory role inthe entry into mitosis. As discussed in the next section, Rad21is related functionally to 20S cyclosome. Rad21 could play animportant role in coordinating the cell cycle and the mitoticcheckpoint system through 20S cyclosome. One group reportedthat the radiation-sensitive rad21-45 mutant did not arrestcompletely at G2 in response to DNA damage (AL-KHODAIRY andCARR 1992 ), but the other group did not confirm it (BIRKENBIHLand SUBRAMANI 1992 ). In the rad21-K1 mutant, cells became elongatedafter UV, ${gamma}$ -ray irradiation, and HU exposure, indicating thatG2 delay seems to take place in response to DNA damage or incompleteDNA synthesis in the mutant (K. TATEBAYASHI, J. KATO and H.IKEDA, unpublished results). Further characterization is neededto know the involvement of Rad21 in the checkpoint control systems.

Possible involvement of Rad21 in ubiquitin-mediated proteolysis pathway:
The cut9 rad21 double mutant is defective in mitosis and didnot grow at 30°. Cut9 is a component of the 20S cyclosome(YAMASHITA et al. 1996 ), which has ubiquitin-ligase activityand is required for cyclin destruction and sister chromatidseparation. The genetic interaction between rad21 and cut9 mutantssuggests that the Rad21 protein may be involved in the ubiquitin-mediatedproteolysis pathway. The 20S cyclosome plays an essential rolein the metaphase-anaphase transition. In addition, 20S cyclosomeis supposed to be required for various cellular functions suchas regulation of DNA replication (HEICHMAN and ROBERTS 1996), spindle assembly and disassembly (JUANG et al. 1997 ), cellshape and cytokinesis (ISHII et al. 1996 ). A close relationof Rad21 to the ubiquitin-mediated proteolysis could explainthe pleiotropic effects of the rad21-K1 mutation. The rad21-K1cells displayed the condensed chromosomes with short spindles,or the chromosomes stretched or unequally segregated with elongatingspindles at the restrictive temperature. Rad21 may be concernedwith metaphase-anaphase transition and/or anaphase progressionby collaboration with the 20S cyclosome. Introduction of theplasmids carrying the nuc2 ⁺ and cut9 ⁺ genes suppressed-temperaturesensitivity of the ${Delta}$ sds23 strain, which is defective in the progressionof anaphase (ISHII et al. 1996 ), indicating that the 20S cyclosomemay be required for the progression of anaphase as well as metaphase-anaphasetransition. However, Rad21 may not be a component of 20S cyclosomebecause chromosomes of the rad21-K1 mutant were stretched orunequally segregated with an elongating spindle, and this phenotypehas not been observed frequently in the cut9 mutant.

In budding yeast, the APC-mediated degradation of the Ase1 protein,a microtubule-binding protein, appears to be required for promptdisassembly of the mitotic spindle at the end of mitosis (JUANGet al. 1997 ). It is possible that Rad21 may regulate spindleassembly or disassembly through proteolysis of microtubule-associatingproteins. Interestingly, the fission yeast cells harboring themutation in the hus5⁺ gene exhibit several phenotypes to thoseof the rad21-K1 mutant. The hus5 mutant undergoes aberrant mitosisand is sensitive to radiation and HU (AL-KHODAIRY et al. 1995). The hus5⁺ gene codes for a ubiquitin-conjugating enzyme (E2);(AL-KHODAIRY et al. 1995 ) and Ubc9, its homolog in buddingyeast, is implicated in the proteolysis of mitotic cyclins (SEUFERTet al. 1995 ), although Ubc9 appears unlikely to participatein D box-dependent proteolysis (IRNIGER et al. 1995 ; KINGet al. 1995 ; ZACHARIAE and NASMYTH 1996 ). Thus, ubiquitin-mediatedproteolysis is important for the microtubule function, DNA repair,and DNA replication. Rad21 may be involved in these biologicalevents as well as proper segregation of chromosomes by regulatingor modifying the function of 20S cyclosome directly or indirectly.However, it has not been clarified whether Rad21 is certainlyrequired for ubiquitin-mediated proteolysis via the 20S cyclosome.Tests for the stability of mitotic cyclin or Cut2 protein inthe rad21-K1 mutant is under study.

ACKNOWLEDGMENTS

We thank M. YANAGIDA and T. TAKEDA for plasmids and strains.We are also grateful to T. MIYAKE for helpful advice with FACScananalysis and to S. J. HEO for critical reading of the manuscript.This work was supported by a grant from the Ministry of Education,Science and Culture of Japan.

Manuscript received April 14, 1997; Accepted for publication September 22, 1997.

LITERATURE CITED

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

ADACHI, Y. and M. YANAGIDA, 1989 Higher order chromosome structure is affected by cold-sensitive mutations in a Schizosaccharomyces pombe gene crm1⁺ which encodes a 115-kD protein preferentially localized in the nucleus and its periphery. J. Cell Biol. 108:1195-1207[Abstract/Free Full Text].

AL-KHODAIRY, F. and A. M. CARR, 1992 DNA repair mutants defining G2 checkpoint pathways in Schizosaccharomyces pombe.. EMBO J. 11:1343-1350[Medline].

AL-KHODAIRY, F., T. ENOCH, I. M. HAGAN, and A. M. CARR, 1995 The Schizosaccharomyces pombe hus5 gene encodes a ubiquitin conjugating enzyme required for normal mitosis. J. Cell Sci. 108:475-486[Abstract].

BIRKENBIHL, R. P. and S. SUBRAMANI, 1992 Cloning and characterization of rad21 an essential gene of Schizosaccharomyces pombe involved in DNA double-strand-break repair. Nucleic Acids Res. 20:6605-6611[Abstract/Free Full Text].

BIRKENBIHL, R. P. and S. SUBRAMANI, 1995 The rad21 gene product of Schizosaccharomyces pombe is a nuclear, cell cycle-regulatedphosphoprotein. J. Biol. Chem. 270:7703-7711[Abstract/Free Full Text].

CROSS, S. M., C. A. SANCHEZ, C. A. MORGAN, M. K. SCHIMKE, and S. RAMEL et al., 1995 A p53-dependent mouse spindle checkpoint. Science 267:1353-1356[Abstract/Free Full Text].

FUNABIKI, H., H. YAMANO, K. KUMADA, K. NAGAO, and T. HUNT et al., 1996 Cut2 proteolysis required for sister-chromatid seperation in fission yeast. Nature 381:438-441[Medline].

GUTZ, H., H. HESLOT, U. LEUPOLD and N. LOPRENO, 1974 Schizosaccharomyces pombe, pp. 395–446 in Handbook of Genetics, Vol. 1, edited by R. C. KING. Plenum Press, New York.

HAGAN, I. and M. YANAGIDA, 1990 Novel potential mitotic motor protein encoded by the fission yeast cut7⁺ gene. Nature 347:563-566[Medline].

HAGAN, I. M. and J. S. HYAMS, 1988 The use of cell division cycle mutants to investigate the control of microtubule distribution in the fission yeast Schizosaccharomyces pombe.. J. Cell Sci. 89:343-357[Abstract/Free Full Text].

HARTWELL, L. H. and T. A. WEINERT, 1989 Checkpoints: controls that ensure the order of cell cycle events. Science 246:629-634[Abstract/Free Full Text].

HEICHMAN, K. A. and J. M. ROBERTS, 1996 The yeast CDC16 and CDC27 genes restrict DNA replication to once per cell cycle. Cell 85:39-48[Medline].

HIRANO, T., S. FUNAHASHI, T. UEMURA, and M. YANAGIDA, 1986 Isolation and characterization of Schizosaccharomyces pombe cut mutants that block nuclear division but not cytokinesis. EMBO J. 5:2973-2979[Medline].

HIRAOKA, Y., T. TODA, and M. YANAGIDA, 1984 The NDA3 gene of fission yeast encodes ß-tubulin: a cold-sensitive nda3 mutation reversibly blocks spindle formation and chromosome movement in mitosis. Cell 39:349-358[Medline].

HOYT, M. A., L. TOTIS, and B. T. ROBERTS, 1991 S. cerevisiae genes required for cell cycle arrest in response to loss of microtubule function. Cell 66:507-517[Medline].

IRNIGER, S., S. PIATTI, C. MICHAELIS, and K. NASMYTH, 1995 Genes involved in sister chromatid separation are needed for B-type cyclin proteolysis in budding yeast. Cell 81:269-278[Medline].

ISHII, K., K. KUMADA, T. TODA, and M. YANAGIDA, 1996 Requirement for PP1 phosphatase and 20S cyclosome/APC for the onset of anaphase is lessened by the dosage increase of a novel gene sds23⁺. EMBO J. 15:6629-6640[Medline].

JAMES, S. W., P. M. MIRABITO, P. C. SCACHERI, and N. R. MORRIS, 1995 The Aspergillus nidulans bimE (blocked-in-mitosis) gene encodes multiple cell cycle functions involved in mitotic checkpoint control and mitosis. J. Cell Sci. 108:3485-3499[Abstract].

JIMENEZ, G., J. YUCEL, R. ROWLEY, and S. SUBRAMANI, 1992 The rad3⁺ gene of Schizosaccharomyces pombe is involved in multiple checkpoint functions and in DNA repair. Proc. Natl. Acad. Sci. USA 89:4952-4956[Abstract/Free Full Text].

JUANG, Y.-L., J. HUANG, J.-M. PETERS, M. E. MCLAUGHLIN, and C.-Y. TAI et al., 1997 APC-mediated proteolysis of Ase1 and the morphogenesis of the mitotic spindle. Science 275:1311-1314[Abstract/Free Full Text].

KING, R. W., J. M. PETERS, S. TUGENDREICH, M. ROLFE, and P. HIETER et al., 1995 A 20S complex containing CDC27 and CDC16 catalyzes the mitosis-specific conjugation of ubiquitin to cyclin B. Cell 81:279-288[Medline].

LAMB, J. R., W. A. MICHAUD, R. S. SIKORSKI, and P. A. HIETER, 1994 Cdc16p, Cdc23p and Cdc27p form a complex essential for mitosis. EMBO J. 13:4321-4328[Medline].

LI, R. and A. W. MURRAY, 1991 Feedback control of mitosis in budding yeast. Cell 66:519-531[Medline].

MAUNDRELL, K., 1993 TATA box mutations in the Schizosaccharomyces pombe nmt1 promoter affects transcription efficiency but not the transcription start point or thiamine repressibility. Gene 123:131-136[Medline].

MILNE, G. T., S. JIN, K. B. SHANNON, and D. T. WEAVER, 1996 Mutations in two Ku homologs define a DNA end-joining repair pathway in Saccharomyces cerevisiae.. Mol. Cell. Biol. 16:4189-4198[Abstract].

MORENO, S., A. KLAR, and P. NURSE, 1991 Molecular genetic analysis of fission yeast Schizosaccharomyces pombe.. Methods Enzymol. 194:795-823[Medline].

OKAZAKI, K., N. OKAZAKI, K. KUME, S. JINNO, and K. TANAKA et al., 1990 High-frequency transformation method and library transducing vectors for cloning mammalian cDNAs by trans-complementation of Schizosaccharomyces pombe.. Nucleic Acids Res. 18:6485-6489[Abstract/Free Full Text].

OSMANI, S. A., D. B. ENGLE, J. H. DOONAN, and N. R. MORRIS, 1988 Spindle formation and chromatin condensation in cells blocked at interphase by mutation of a negative cell cycle control gene. Cell 52:241-251[Medline].

OSMANI, A. H., K. O'DONNELL, R. T. PU, and S. A. OSMANI, 1991 Activation of the nimA protein kinase plays a unique role during mitosis that cannot be bypassed by absence of the bimE checkpoint. EMBO J. 10:2669-2679[Medline].

PETERS, J.-M., R. W. KING, C. HOOG, and M. W. KIRSCHNER, 1996 Identification of BIME as a subunit of the anaphase-promoting complex. Science 274:1199-1201[Abstract/Free Full Text].

PHIPPS, J., A. NASIM, and D. R. MILLER, 1985 Recovery, repair, and mutagenesis in Schizosaccharomyces pombe.. Adv. Genet. 23:1-72[Medline].

SAKA, Y. and M. YANAGIDA, 1993 Fission yeast cut5⁺, required for S phase onset and M phase restraint, is identical to the radiation-damage repair gene rad4⁺. Cell 74:383-393[Medline].

SAKA, Y., T. SUTANI, Y. YAMASHITA, S. SAITOH, and M. TAKEUCHI et al., 1994a Fission yeast cut3 and cut14, members of a ubiquitous protein family, are required for chromosome condensation and segregation in mitosis. EMBO J. 13:4938-4952[Medline].

SAKA, Y., P. FANTES, T. SUTANI, C. MCINERNY, and J. CREANOR et al., 1994b Fission yeast cut5 links nuclear chromatin and M phase regulator in the replication checkpoint control. EMBO J. 13:5319-5329[Medline].

SAMEJIMA, I., T. MATSUMOTO, Y. NAKASEKO, D. BEACH, and M. YANAGIDA, 1993 Identification of seven new cut genes involved in Schizosaccharomyces pombe mitosis. J. Cell Sci. 105:135-143[Abstract].

SAMEJIMA, I. and M. YANAGIDA, 1994a Identification of cut8⁺ and cek1⁺, a novel protein kinase gene, which complement a fission yeast mutation that blocks anaphase. Mol. Cell. Biol. 14:6361-6371[Abstract/Free Full Text].

SAMEJIMA, I. and M. YANAGIDA, 1994b Bypassing anaphase by fission yeast cut9 mutation: requirement of cut9⁺ to initiate anaphase. J. Cell Biol. 127:1655-1670[Abstract/Free Full Text].

SEUFERT, W., B. FUTCHER, and S. JENTSCH, 1995 Role of a ubiquitin-conjugating enzyme in degradation of S- and M-phase cyclins. Nature 373:78-81[Medline].

SHIMIZU, H., H. YAMAGUCHI, Y. ASHIZAWA, Y. KOHNO, and M. ASAMI et al., 1997 Short–homology-independent illegitimate recombination in Escherichia coli: distinct mechanism from short-homology-dependent illegitimate recombination. J. Mol. Biol. 266:297-305[Medline].

TODA, T., K. UMESONO, A. HIRATA, and M. YANAGIDA, 1983 Cold-sensitive nuclear division arrest mutants of the fission yeast Schizosaccharomyces pombe.. J. Mol. Biol. 168:251-270[Medline].

TODA, T., Y. ADACHI, Y. HIRAOKA, and M. YANAGIDA, 1984 Identifica-tion of the pleiotropic cell division cycle gene NDA2 as one of two different ${alpha}$ -tubulin genes in Schizosaccharomyces pombe. Cell 37:233-242[Medline].

UEMURA, T. and M. YANAGIDA, 1986 Mitotic spindle pulls but fails to septate chromosomes in type II DNA topoisomerase mutants: uncoordinated mitosis. EMBO J. 5:1003-1010[Medline].

UMESONO, K., T. TODA, S. HAYASHI, and M. YANAGIDA, 1983 Two cell division cycle genes NDA2 and NDA3 of the fission yeast Schizosaccharomyces pombe control microtubular organization and sensitivity to anti-mitotic benzimidazole compounds. J. Mol. Biol. 168:271-284[Medline].

UZAWA, S., I. SAMEJIMA, T. HIRANO, K. TANAKA, and M. YANAGIDA, 1990 The fission yeast cut1⁺ gene regulates spindle pole body duplication and has homology to the budding yeast ESP1 gene. Cell 62:913-925[Medline].

YAMAMOTO, A., V. GUACCI, and D. KOSHLAND, 1996 Pds1p, an inhibitor of anaphase in budding yeast, plays a critical role in the APC and checkpoint pathway(s). J. Cell Biol. 133:99-110[Abstract/Free Full Text].

YAMASHITA, Y. M., Y. NAKASEKO, I. SAMEJIMA, K. KUMADA, and H. YAMADA et al., 1996 20S cyclosome complex formation and proteolytic activity inhibited by the cAMP/PKA pathway. Nature 384:276-279[Medline].

ZACHARIAE, W. and K. NASMYTH, 1996 TPR proteins required for anaphaseprogression mediate ubiquitination of mitotic B-type cyclins in yeast. Mol. Biol. Cell 7:791-801[Abstract].

ZACHARIAE, W., T. H. SHIN, M. GALOVA, B. OBERMAIER, and K. NASMYTH, 1996 Identification of subunits of the anaphase-promoting complex of Saccharomyces cerevisiae.. Science 274:1201-1204[Abstract/Free Full Text].

This article has been cited by other articles:

G. Hallson, M. Syrzycka, S. A. Beck, J. A. Kennison, D. Dorsett, S. L. Page, S. M. Hunter, R. Keall, W. D. Warren, H. W. Brock, et al.
From the Cover: The Drosophila cohesin subunit Rad21 is a trithorax group (trxG) protein
PNAS, August 26, 2008; 105(34): 12405 - 12410.
[Abstract] [Full Text] [PDF]

Y. Tange and O. Niwa
Schizosaccharomyces pombe Bub3 Is Dispensable for Mitotic Arrest Following Perturbed Spindle Formation
Genetics, June 1, 2008; 179(2): 785 - 792.
[Abstract] [Full Text] [PDF]

Y. Kimata, A. Matsuyama, K. Nagao, K. Furuya, C. Obuse, M. Yoshida, and M. Yanagida
Diminishing HDACs by drugs or mutations promotes normal or abnormal sister chromatid separation by affecting APC/C and adherin
J. Cell Sci., April 1, 2008; 121(7): 1107 - 1118.
[Abstract] [Full Text] [PDF]

A. B. Ansbach, C. Noguchi, I. W. Klansek, M. Heidlebaugh, T. M. Nakamura, and E. Noguchi
RFCCtf18 and the Swi1-Swi3 Complex Function in Separate and Redundant Pathways Required for the Stabilization of Replication Forks to Facilitate Sister Chromatid Cohesion in Schizosaccharomyces pombe
Mol. Biol. Cell, February 1, 2008; 19(2): 595 - 607.
[Abstract] [Full Text] [PDF]

K. M. Lee, S. Nizza, T. Hayes, K. L. Bass, A. Irmisch, J. M. Murray, and M. J. O'Connell
Brc1-Mediated Rescue of Smc5/6 Deficiency: Requirement for Multiple Nucleases and a Novel Rad18 Function
Genetics, April 1, 2007; 175(4): 1585 - 1595.
[Abstract] [Full Text] [PDF]

K. Asakawa, K. Kume, M. Kanai, T. Goshima, K. Miyahara, S. Dhut, W. W. Tee, D. Hirata, and T. Toda
The V260I Mutation in Fission Yeast {alpha}-Tubulin Atb2 Affects Microtubule Dynamics and EB1-Mal3 Localization and Activates the Bub1 Branch of the Spindle Checkpoint
Mol. Biol. Cell, March 1, 2006; 17(3): 1421 - 1435.
[Abstract] [Full Text] [PDF]

S. W. Bai, J. Rouquette, M. Umeda, W. Faigle, D. Loew, S. Sazer, and V. Doye
The Fission Yeast Nup107-120 Complex Functionally Interacts with the Small GTPase Ran/Spi1 and Is Required for mRNA Export, Nuclear Pore Distribution, and Proper Cell Division
Mol. Cell. Biol., July 15, 2004; 24(14): 6379 - 6392.
[Abstract] [Full Text] [PDF]

S. H. Harvey, D. M. Sheedy, A. R. Cuddihy, and M. J. O'Connell
Coordination of DNA Damage Responses via the Smc5/Smc6 Complex
Mol. Cell. Biol., January 15, 2004; 24(2): 662 - 674.
[Abstract] [Full Text] [PDF]

S. Yokobayashi, M. Yamamoto, and Y. Watanabe
Cohesins Determine the Attachment Manner of Kinetochores to Spindle Microtubules at Meiosis I in Fission Yeast
Mol. Cell. Biol., June 1, 2003; 23(11): 3965 - 3973.
[Abstract] [Full Text] [PDF]

Y. Mito, A. Sugimoto, and M. Yamamoto
Distinct Developmental Function of Two Caenorhabditis elegans Homologs of the Cohesin Subunit Scc1/Rad21
Mol. Biol. Cell, June 1, 2003; 14(6): 2399 - 2409.
[Abstract] [Full Text] [PDF]

Md. T. Hoque and F. Ishikawa
Cohesin Defects Lead to Premature Sister Chromatid Separation, Kinetochore Dysfunction, and Spindle-assembly Checkpoint Activation
J. Biol. Chem., October 25, 2002; 277(44): 42306 - 42314.
[Abstract] [Full Text] [PDF]

D. R. Williams and J. R. McIntosh
mcl1+, the Schizosaccharomyces pombe Homologue of CTF4, Is Important for Chromosome Replication, Cohesion, and Segregation
Eukaryot. Cell, October 1, 2002; 1(5): 758 - 773.
[Abstract] [Full Text] [PDF]

				Y. Tange and O. Niwa Schizosaccharomyces pombe Bub3 Is Dispensable for Mitotic Arrest Following Perturbed Spindle Formation Genetics, June 1, 2008; 179(2): 785 - 792. [Abstract] [Full Text] [PDF]

				Y. Kimata, A. Matsuyama, K. Nagao, K. Furuya, C. Obuse, M. Yoshida, and M. Yanagida Diminishing HDACs by drugs or mutations promotes normal or abnormal sister chromatid separation by affecting APC/C and adherin J. Cell Sci., April 1, 2008; 121(7): 1107 - 1118. [Abstract] [Full Text] [PDF]

				A. B. Ansbach, C. Noguchi, I. W. Klansek, M. Heidlebaugh, T. M. Nakamura, and E. Noguchi RFCCtf18 and the Swi1-Swi3 Complex Function in Separate and Redundant Pathways Required for the Stabilization of Replication Forks to Facilitate Sister Chromatid Cohesion in Schizosaccharomyces pombe Mol. Biol. Cell, February 1, 2008; 19(2): 595 - 607. [Abstract] [Full Text] [PDF]

				K. M. Lee, S. Nizza, T. Hayes, K. L. Bass, A. Irmisch, J. M. Murray, and M. J. O'Connell Brc1-Mediated Rescue of Smc5/6 Deficiency: Requirement for Multiple Nucleases and a Novel Rad18 Function Genetics, April 1, 2007; 175(4): 1585 - 1595. [Abstract] [Full Text] [PDF]

				K. Asakawa, K. Kume, M. Kanai, T. Goshima, K. Miyahara, S. Dhut, W. W. Tee, D. Hirata, and T. Toda The V260I Mutation in Fission Yeast {alpha}-Tubulin Atb2 Affects Microtubule Dynamics and EB1-Mal3 Localization and Activates the Bub1 Branch of the Spindle Checkpoint Mol. Biol. Cell, March 1, 2006; 17(3): 1421 - 1435. [Abstract] [Full Text] [PDF]

				S. W. Bai, J. Rouquette, M. Umeda, W. Faigle, D. Loew, S. Sazer, and V. Doye The Fission Yeast Nup107-120 Complex Functionally Interacts with the Small GTPase Ran/Spi1 and Is Required for mRNA Export, Nuclear Pore Distribution, and Proper Cell Division Mol. Cell. Biol., July 15, 2004; 24(14): 6379 - 6392. [Abstract] [Full Text] [PDF]

				S. H. Harvey, D. M. Sheedy, A. R. Cuddihy, and M. J. O'Connell Coordination of DNA Damage Responses via the Smc5/Smc6 Complex Mol. Cell. Biol., January 15, 2004; 24(2): 662 - 674. [Abstract] [Full Text] [PDF]

				S. Yokobayashi, M. Yamamoto, and Y. Watanabe Cohesins Determine the Attachment Manner of Kinetochores to Spindle Microtubules at Meiosis I in Fission Yeast Mol. Cell. Biol., June 1, 2003; 23(11): 3965 - 3973. [Abstract] [Full Text] [PDF]

				Y. Mito, A. Sugimoto, and M. Yamamoto Distinct Developmental Function of Two Caenorhabditis elegans Homologs of the Cohesin Subunit Scc1/Rad21 Mol. Biol. Cell, June 1, 2003; 14(6): 2399 - 2409. [Abstract] [Full Text] [PDF]

				Md. T. Hoque and F. Ishikawa Cohesin Defects Lead to Premature Sister Chromatid Separation, Kinetochore Dysfunction, and Spindle-assembly Checkpoint Activation J. Biol. Chem., October 25, 2002; 277(44): 42306 - 42314. [Abstract] [Full Text] [PDF]

				D. R. Williams and J. R. McIntosh mcl1+, the Schizosaccharomyces pombe Homologue of CTF4, Is Important for Chromosome Replication, Cohesion, and Segregation Eukaryot. Cell, October 1, 2002; 1(5): 758 - 773. [Abstract] [Full Text] [PDF]