cyd,a mutant of pea that alters embryo morphology is defective in cytokinesis

Embryogenesis in higher plants requires the precise regulation of cell division, orientation of cell elongation and specification of cell differentiation. The division plane is determined by the position of a new cell plate at cytokinesis. A mutant of pea has been isolated in which both the embryo pattern and surface morphology is altered. The phenotype of the mutant is manifest primarily in the cotyledons where cell plates only partially form, generating cell wall stubs and multinucleate cells. Some cotyledonary cells of the mutant proceed through nine DNA replication cycles, including nuclear division, but not cytokinesis, producing nuclei with a DNA content of ca. 1000C. The cytological phenotype of the mutant could be mimicked by the treatment of wild-type cells with caffeine. We have termed this mutant cytokinesis-defective (cyd). © 1995 Wiley-Liss, Inc.     

Topoisomerase III is required for accurate DNA replication and chromosome segregation in Schizosaccharomyces pombe

The deletion of the top3⁺ gene leads to defective nuclear division and lethality in Schizosaccharo myces pombe. This lethality is suppressed by concomitant loss of rqh1⁺, the RecQ helicase. Despite extensive investigation, topoisomerase III function and its relationship with RecQ helicase remain poorly understood. We generated top3 temperature-sensitive (top3-ts) mutants and found these to be defective in nuclear division and cytokinesis and to be sensitive to DNA-damaging agents. A temperature shift of top3-ts cells to 37°C, or treatment with hydroxyurea at the permissive temperature, caused an increase in ‘cut’ (cell untimely torn) cells and elevated rates of minichromosome loss. The viability of top3-ts cells was decreased by a temperature shift during S-phase when compared with a similar treatment in other cell cycle stages. Furthermore, the top3-ts mutant was not sensitive to M-phase specific drugs. These results indicate that topoisomerase III may play an important role in DNA metabolism during DNA replication to ensure proper chromosome segregation. Our data are consistent with Top3 acting downstream of Rqh1 to process the toxic DNA structure produced by Rqh1.     

Cold-Sensitive Cell-Division-Cycle Mutants of Yeast: Isolation, Properties, and Pseudoreversion Studies

We isolated 18 independent recessive cold-sensitive cell-division-cycle (cdc) mutants of Saccharomyces cerevisiae, in nine complementation groups. Terminal phenotypes exhibited include medial nuclear division, cytokinesis, and a previously undescribed terminal phenotype consisting of cells with a single small bud and an undivided nucleus. Four of the cold-sensitive mutants proved to be alleles of CDC11, while the remaining mutants defined at least six new cell-division-cycle genes: CDC44, CDC45, CDC48, CDC49, CDC50 and CDC51.—Spontaneous revertants from cold-sensitivity of four of the medial nuclear division cs cdc mutants were screened for simultaneous acquisition of a temperature-sensitive phenotype. The temperature-sensitive revertants of four different cs cdc mutants carried single new mutations, called Sup/Ts to denote their dual phenotype: suppression of the cold-sensitivity and concomitant conditional lethality at 37°. Many of the Sup/Ts mutations exhibited a cell-division-cycle terminal phenotype at the high temperature, and they defined two new cdc genes (CDC46 and CDC47). Two cold-sensitive medial nuclear division cdc mutants representing two different cdc genes were suppressed by different Sup/Ts alleles of another gene which also bears a medial nuclear division function (CDC46). In addition, the cold-sensitive medial nuclear division cdc mutant csH80 was suppressed by a Sup/Ts mutation yielding an unbudded terminal phenotype with an undivided nucleus at the high temperature. This mutation was an allele of CDC32. These results suggest a pattern of interaction among cdc gene products and indicate that cdc gene proteins might act in the cell cycle as complex specific functional assemblies.     

Mitotic spindle pulls but fails to separate chromosomes in type II DNA topoisomerase mutants: uncoordinated mitosis

The fission yeast top2 locus is defined by five temperature-sensitive mutations that cause heat-labile activity of type II DNA topoisomerase in the cell extracts. We show that the top2 locus is a structural gene for type II topoisomerase by cloning a genomic DNA fragment that complements top2. The top2 mutants at restrictive temperature produce abnormal chromosomes at the time of mitosis; these are transiently extended into filamentous structures along with the elongating mitotic spindle but are not separated. A primary defect in top2 appears to be the formation of aberrant mitotic chromosomes inseparable by the force generated by the spindle apparatus. Consistently, the top2 cells that become lethal during mitosis contain a catenated dimer of an ARS plasmid. DNA and RNA continue to be synthesized if cytokinesis is blocked. Uncoordinated mitosis, that is the occurrence of spindle dynamics without chromosome separation, is revealed in top2, and is discussed in relation to mitotic regulation. Different phenotypes between top2 and top1-top2 described in the present paper can be explained by a previously proposed hypothesis that type II topoisomerase has dual in vivo functions: one that decatenates and unknots duplex DNAs is essential in mitosis, whereas the other which relaxes supercoils is required throughout the cell cycle if type I topoisomerase is absent.     

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

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

Isolation of type I and II DNA topoisomerase mutants from fission yeast: single and double mutants show different phenotypes in cell growth and chromatin organization.

We have isolated mutants defective in DNA topoisomerases and an endonuclease from the fission yeast Schizosaccharomyces pombe by screening individual extracts of mutagenized cells. Two type I topoisomerase mutants (top1) and three endonuclease mutants (end1) were all viable. The double mutant top1 end1 was also viable and, in its extract, Mg2+- and ATP- dependent type II activity could be detected. Three temperature-sensitive (ts-) mutants having heat-sensitive (hs-) type II enzymes were isolated, and the ts- marker cosegregated with the hs- type II activity. All the ts- mutations fell in one gene (top2) tightly linked to leul in chromosome II. The nuclear division of single top2 mutants was blocked at the restrictive temperature, but the formation of a septum was not inhibited so that the nucleus was cut across with the cell plate. In contrast, the double top1 top2 mutants were rapidly arrested at various stages of the cell cycle, showing a strikingly altered nuclear chromatin region. The type II topoisomerase may have an essential role in the compaction and/or segregation of chromosomes during the nuclear division but also complement the defect of the type I enzyme whose major function is the maintenance of chromatin organization throughout the cell cycle.     

The Role of Topoisomerase II in Meiotic Chromosome Condensation and Segregation in Schizosaccharomyces pombe

Topoisomerase II is able to break and rejoin double-strand DNA. It controls the topological state and forms and resolves knots and catenanes. Not much is known about the relation between the chromosome segregation and condensation defects as found in yeast top2 mutants and the role of topoisomerase II in meiosis. We studied meiosis in a heat-sensitive top2 mutant of Schizosaccharomyces pombe. Topoisomerase II is not required until shortly before meiosis I. The enzyme is necessary for condensation shortly before the first meiotic division but not for early meiotic prophase condensation. DNA replication, prophase morphology, and dynamics of the linear elements are normal in the top2 mutant. The top2 cells are not able to perform meiosis I. Arrested cells have four spindle pole bodies and two spindles but only one nucleus, suggesting that the arrest is nonregulatory. Finally, we show that the arrest is partly solved in a top2 rec7 double mutant, indicating that topoisomerase II functions in the segregation of recombined chromosomes. We suggest that the inability to decatenate the replicated DNA is the primary defect in top2. This leads to a loss of chromatin condensation shortly before meiosis I, failure of sister chromatid separation, and a nonregulatory arrest.     

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.     

Topoisomerase III is essential for accurate nuclear division in Schizosaccharomyces pombe.

Topoisomerases catalyse changes in the topological state of DNA and are required for many aspects of DNA metabolism. While the functions of topoisomerases I and II in eukaryotes are well established, the role of topoisomerase III remains poorly defined. We have identified a gene in the fission yeast Schizosaccharomyces pombe, designated top3 (+), which shows significant sequence similarity to genes encoding topoisomerase III enzymes in other eukaryotic species. In common with murine TOP3 alpha, but in contrast to Saccharomyces cerevisiae TOP3, the S.pombe top3 (+)gene is essential for long-term cell viability. Fission yeast haploid spores containing a disrupted top3 (+)gene germinate successfully, but then undergo only a limited number of cell divisions. Analysis of these top3 mutants revealed evidence of aberrant mitotic chromosome segregation, including the 'cut' phenotype, where septation is completed prior to nuclear division. Consistent with the existence of an intimate association (originally identified in S.cerevisiae ) between topoisomerase III and DNA helicases of the RecQ family, deletion of the rqh1 (+)gene encoding the only known RecQ helicase in S.pombe suppresses lethality in top3 mutants. This conservation of genetic interaction between two widely diverged yeasts suggests that the RecQ family helicases encoded by the Bloom's and Werner's syndrome genes are likely to act in concert with topoisomerase III isozymes in human cells. Our data are consistent with a model in which the association of a RecQ helicase and topoisomerase III is important for facilitating decatenation of late stage replicons to permit faithful chromosome segregation during anaphase.     

Drc1p/Cps1p, a 1,3-beta-glucan synthase subunit, is essential for division septum assembly in Schizosaccharomyces pombe.

Schizosaccharomyces pombe divides by medial fission through the use of an actomyosin-based contractile ring. A division septum is formed centripetally, concomitant with ring constriction. Although several genes essential for cytokinesis have been described previously, enzymes that participate in the assembly of the division septum have not been identified. Here we describe a temperature-sensitive mutation, drc1-191, that prevents division septum assembly and causes mutant cells to arrest with a stable actomyosin ring. Unlike the previously characterized cytokinesis mutants, which undergo multiple mitotic cycles, drc1-191 is the first cytokinesis mutant that arrests with two interphase nuclei. Interestingly, unlike drc1-191, drc1-null mutants proceed through multiple mitotic cycles, leading to the formation of large cells with many nuclei. drc1 is allelic to cps1, which encodes a 1,3-beta-glucan synthase subunit. We conclude that Drc1p/Cps1p is not required for cell elongation and cell growth, but plays an essential role in assembly of the division septum. Furthermore, it appears that constriction of the actomyosin ring might depend on assembly of the division septum. We discuss possible mechanisms that account for the differences in the phenotypes of the drc1-191 and the drc1-null mutants and also reflect the potential links between Drc1p and other cytokinesis regulators.     

A new Drosophila gene wh (wuho) with WD40 repeats is essential for spermatogenesis and has maximal expression in hub cells

Through mutagenesis by P-element transposition, we identified a series of mutants with deletions in topoisomerase 3beta gene (top3beta) and an adjacent, previously uncharacterized gene CG15897, here named wuho (wh). Whereas top3beta truncation does not affect viability or fertility, wh null mutants display male sterile and female semi-sterile phenotypes. Furthermore, wh mutants can be fully rescued by wh transgenes, but not by top3beta transgenes, suggesting that the fertility phenotypes are caused by wh deletion. The alignment of WH protein sequence with other eukaryotic putative homologues shows they are evolutionarily conserved proteins with 5 WD40 repeats in the middle portion of the protein, and a bipartite nuclear localization signal at the carboxyl terminus. Yeast homologue with 5 WD40 repeats, Trm82, is the non-catalytic subunit of a tRNA methylase. Immunostaining shows that WH has the highest expression in hub cells, a niche for germline stem cells of testis. However, WH is not required for the maintenance of hub cells or the germline stem cells. In wh mutant males, spermatogenesis is arrested at the elongating stage of the developing spermatids, resulting in an absence of mature sperms in the seminal vesicles. The decreased fertility in wh mutant females is mostly due to defects in oogenesis. There are abnormal egg chambers present in the mutant females, in which the cystocytes fail to arrest their cell division at the fourth mitotic cycle, resulting in more than 16 cells in a single egg chamber. Additionally, these abnormal cystocytes do not undergo multiple rounds of endoreplication as the nurse cells do in a normal egg chamber. Therefore, the cytological analyses demonstrate that wh has a critical function in cellular differentiation for germline cells during gametogenesis.     

Cdc20, a β-transducin homologue,links RAD9-mediated G2/M checkpoint control to mitosis in Saccharomyces cerevisiae

In the budding yeast Saccharomyces cerevisiae, the DNA damage-induced G2 arrest requires the checkpoint control genes RAD9, RAD17, RAD24, MEC1, MEC2 and MEC3. These genes also prevent entry into mitosis of a temperature-sensitive mutant, cdc13, that accumulates chromosome damage at 37^°?C. Here we show that a cdc13 mutant overexpressing Cdc20, a β-transducin homologue, no longer arrests in G2 at the restrictive temperature but instead undergoes nuclear division, exits mitosis and enters a subsequent division cycle, which suggests that the DNA damage-induced G2/M checkpoint control is not functional in these cells. This is consistent with our observation that overexpression of CDC20 in wild-type cells results in increased sensitivity to UV irradiation. Overproduction of Cdc20 does not influence the arrest phenotype of the cdc mutants whose cell cycle block is independent of RAD9-mediated checkpoint control. Therefore, we suggest that the DNA damage-induced checkpoint controls prevent mitosis by inhibiting the nuclear division pathway requiring CDC20 function.     

Human DNA topoisomerases IIα and IIβ can functionally substitute for yeastTOP2 in chromosome segregation and recombination

The ability of the human DNA topoisomerase IIα and IIβ isozymes to complement functional defects conferred by conditionaltop2 mutations inSaccharomyces cerevisiae has been investigated. At the restrictive temperature,top2 strains show multiple abnormalities, including an inability to complete mitotic and meiotic division owing to a defect in chromosome segregation, and hyper-recombination within the repetitive rDNA gene cluster. We show that the human topoisomerases IIα and IIβ can each support both vegetative growth and the production of viable spores in atop2-4 mutant at the restrictive temperature. Similarly, both human isozymes can rescue a strain carrying atop2 gene disruption, and suppress hyper-recombination within the rDNA gene cluster. We conclude that the human topoisomerase IIα and IIβ isozymes are functionally interchangeable with yeast topoisomerase II and suggest that any isozyme-specific roles in human cells are likely to be dependent upon factors other than inherent differences in catalytic ability between the α and β isozymes.     

Cut8, essential for anaphase, controls localization of 26S proteasome, facilitating destruction of cyclin and Cut2

BACKGROUND: Anaphase-promoting complex (APC)/cyclosome and 26S proteasome are respectively required for polyubiquitination and degradation of mitotic cyclin and anaphase inhibitor Cut2 (Pds1/securin). In fission yeast, mutant cells defective in cyclosome and proteasome fail to complete mitosis and have hypercondensed chromosomes and a short spindle. A similar phenotype is seen in a temperature-sensitive strain cut8-563 at 36 degrees C, but the molecular basis for Cut8 function is little understood. RESULTS: At high temperature, the level of Cut8 greatly increases and it becomes essential to the progression of anaphase. In cut8 mutants, chromosome mis-segregation and aberrant spindle dynamics occur, but cytokinesis takes place with normal timing, leading to the cut phenotype. This is due to the fact that destruction of mitotic cyclin and Cut2 in the nucleus is dramatically delayed, though polyubiquitination of Cdc13 occurs in cut8 mutant. Cut8 is localized chiefly to the nucleus and nuclear periphery, a distribution highly similar to that of 26S proteasome. In cut8 mutant, however, 26S proteasome becomes mostly cytoplasmic, showing that Cut8 is needed for its proper localization. CONCLUSION: Cut8 is a novel evolutionarily conserved heat-inducible regulator. It facilitates anaphase-promoting proteolysis by recruiting 26S proteasome to a functionally efficient nuclear location.     

The essential role of yeast topoisomerase III in meiosis depends on recombination

Yeast cells mutant for TOP3, the gene encoding the evolutionary conserved type I-5' topoisomerase, display a wide range of phenotypes including altered cell cycle, hyper-recombination, abnormal gene expression, poor mating, chromosome instability and absence of sporulation. In this report, an analysis of the role of TOP3 in the meiotic process indicates that top3Delta mutants enter meiosis and complete the initial steps of recombination. However, reductional division does not occur. Deletion of the SPO11 gene, which prevents recombination between homologous chromosomes in meiosis I division, allows top3Delta mutants to form viable spores, indicating that Top3 is required to complete recombination successfully. A topoisomerase activity is involved in this process, since expression of bacterial TopA in yeast top3Delta mutants permits sporulation. The meiotic block is also partially suppressed by a deletion of SGS1, a gene encoding a helicase that interacts with Top3. We propose an essential role for Top3 in the processing of molecules generated during meiotic recombination.     

Loss of RecQ5 leads to spontaneous mitotic defects and chromosomal aberrations in Drosophila melanogaster

RecQ5 belongs to the RecQ DNA helicase family that includes genes causative of Bloom, Werner, and Rothmund-Thomson syndromes. Although no human disease has been genetically linked to a mutation in RecQ5, Drosophila melanogaster RecQ5 is highly expressed in early embryos, suggesting an important role for it in the DNA metabolism of the early embryo. In this present study, we generated RecQ5 mutants in D. melanogaster. Embryos lacking maternally derived RecQ5 contained irregular nuclei in early embryogenesis. These irregular nuclei emerged in nuclear cycle 11–13, lost cell-cycle markers, and were located below the surface monolayer of nuclei. By time-lapse microscopy, these irregular nuclei were observed not to divide, whereas all neighboring nuclei proceeded through normal mitotic division with synchrony. These data suggest that the irregular nuclei exited from the nuclear division cycle. This phenotype is reminiscent of the effect of X-ray irradiation on wild-type embryos and was rescued by expression of RecQ5. Thus, the maternal supply of RecQ5 is important for the nuclear cycles in syncytical embryos. Furthermore, the frequencies of spontaneous and induced chromosomal aberrations were increased in RecQ5 mutant neuroblasts. These data imply that DNA damage accumulates spontaneously in RecQ5 mutants. Therefore, endogenous genomic damage may be produced in Drosophila development, and RecQ5 would be involved in the maintenance of genomic stability by suppressing the accumulation of DNA damage.     

The topoisomerase II-associated protein, Pat1p, is required for maintenance of rDNA locus stability in Saccharomyces cerevisiae

The Pat1 protein of Saccharomyces cerevisiae was identified during a screen for proteins that interact with topoisomerase II. Previously, we have shown that pat1Δ mutants exhibit a slow-growth phenotype and an elevated frequency of both mitotic and meiotic chromosome mis-segregation. Here, we have studied the effects of deleting the PAT1 gene on chromosomal stability, with particular reference to rates of homologous recombination within the rDNA locus. This locus was analyzed because rDNA-specific hyperrecombination is known to occur in conditional top2 mutants. We show that pat1Δ strains mimic top2 mutants in displaying an elevated rate of intrachromosomal excision recombination at the rDNA locus, but not elsewhere in the genome. The elevated rate of recombination is dependent upon Rad52p, but not upon Rad51p or Rad54p. However, pat1Δ strains display additional manifestations of more general genomic instability, in that they show mild sensitivity to UV light and an increased incidence of interchromosomal recombination between heteroalleles.