Control of Saccharomyces cerevisiae 2microN DNA replication by cell division cycle genes that control nuclear DNA replication.

The replication of the 2 μm DNA of Saccharomyces cerevisiae has been examined in cell division cycle (cdc) mutants. The 2 μm DNA does not replicate at the restrictive temperature in cells bearing the cdc28, cdc4, and cdc7 mutations which prevent passage of cells from the G1 phase into S phase. Plasmid replication also is prevented in a mating-type cells by α factor, a mating hormone which prevents cells from completing an event early in G1 phase. The 2 μm DNA ceases replication at 36 °C in a mutant harboring the cdc8 mutation, a defect in the elongation reactions of nuclear DNA replication. Plasmid replication continues at the restrictive temperature for approximately one generation in a cdc13 mutant defective in nuclear division. These results show that 2 μm DNA replication is controlled by the same genes that control the initiation and completion of nuclear DNA replication.     

Genetic control of the cell division cycle in yeast : II. Genes controlling DNA replication and its initiation

Temperature-sensitive mutations occurring in two unlinked complementation groups, cdc4 and cdc8, are recessive and result in a defect in DNA replication at the restrictive temperature. Results obtained with synchronous cultures suggest that cdc4 functions in the initiation of DNA replication and cdc8 functions in the propagation of DNA replication.     

Sequential function of gene products relative to DNA synthesis in the yeast cell cycle

An experimental rationale for deciphering the relative dependence of steps in a developmental pathway (Jarvik & Botstein, 1973; Hereford & Hartwell, 1974) has been employed to determine the relationship between the hydroxyurea-sensitive step and various temperature-sensitive steps in the cell cycle of Saccharomyces cerevisiae. Since hydroxyurea inhibits DNA replication in yeast (Slater, 1973), the data identify gene products upon whose function DNA replication is dependent (cdc 4, 6, 7, 2, 8, 21) and gene products whose function or synthesis requires DNA replication (cdc 2, 8, 21, 9, 13, 16, 23, 5, 15). Other gene products (cdc 3, 11, 24) function independent of DNA replication. These results suggest that the events of the cell cycle occur in a proscribed order because many of the gene products that mediate these events arc restricted to a prescribed sequence of function.Mutations in two genes (cdc 2 and 6) result in cells that remain sensitive to hydroxyurea after an incubation at the restrictive temperature, despite the fact that both mutants incorporate radioactive precursors into DNA at the restrictive temperature (Hartwell, 1973). It is suggested that cdc 6 specifies a function that is necessary for the proper initiation of DNA replication, and cdc 2 a function that is necessary for correct DNA elongation, and that in the absence of either of these functions the DNA that is made is either faulty or incomplete.     

Temperature-sensitive lethal mutants in the structural gene for dna ligase in the yeast schizosaccharomyces pombe

cdc 17-K42 was isolated as a temperature-sensitive cdc^? mutant of the fission yeast Schizosaccharomyces pombe after nitrosoguanidine mutagenesis. The temperature-sensitive phenotype segregrates 2:2 in tetrad analyses, and it is recessive to the wild-type allele. The pattern of cell division in this mutant on temperature shift implies that its defective function is usually completed by the end of S phase. Cells of cdc 17-K42 enter S phase and undergo a complete round of DNA synthesis at the restrictive temperature, but mitosis does not follow. The nascent DNA accumulated at the restrictive temperature is exclusively composed of short (Okazaki) fragments. After a 20 min pulse label, the main peak of labeled DNA is from 70–450 nucleotides long. DNA ligase assays, involving the formation of covalently closed λ DNA circles, show that the mutant has low levels of DNA ligase activity (<20%) when assayed at the permissive temperature and none detectable when assayed at the restrictive temperature. This implies that the cdc 17 locus codes for the structural gene for DNA ligase. cdc 17-K42 also has a temperature-enhanced ultraviolet sensitivity, suggesting that the same enzyme is involved in DNA repair. Two other independent mutant alleles in the same gene have also been isolated (M75 and L16). They share many of the above properties.     

Genetic Control of the Cell Division Cycle in Yeast: V. Genetic Analysis of cdc Mutants

One hundred and forty-eight temperature-sensitive cell division cycle (cdc) mutants of Saccharomyces cerevisiae have been isolated and characterized. Complementation studies ordered these recessive mutations into 32 groups and tetrad analysis revealed that each of these groups defines a single nuclear gene. Fourteen of these genes have been located on the yeast genetic map. Functionally related cistrons are not tightly clustered.

Mutations in different cistrons frequently produce different cellular and nuclear morphologies in the mutant cells following incubation at the restrictive temperature, but all the mutations in the same cistron produce essentially the same morphology. The products of these genes appear, therefore, each to function individually in a discrete step of the cell cycle and they define collectively a large number of different steps.

The mutants were examined by time-lapse photomicroscopy to determine the number of cell cycles completed at the restrictive temperature before arrest. For most mutants, cells early in the cell cycle at the time of the temperature shift (before the execution point) arrest in the first cell cycle while those later in the cycle (after the execution point) arrest in the second cell cycle. Execution points for allelic mutations that exhibit first or second cycle arrest are rather similar and appear to be cistron-specific. Other mutants traverse several cycles before arrest, and its suggested that the latter type of response may reveal gene products that are temperature-sensitive for synthesis, whereas the former may be temperature-sensitive for function.

The gene products that are defined by the cdc cistrons are essential for the completion of the cell cycle in haploids of a and α mating type and in a/α diploid cells. The same genes, therefore, control the cell cycle in each of these stages of the life cycle.

     

Temperature-sensitive multicellular mutants of Wangiella dermatitidis.

Three temperature-sensitive morphological mutants of Wangiella dermatitidis were isolated and characterized. The mutants grew in the yeastlike morphology at the permissive temperature (25 degrees C) but expressed a multicellular (Mc) phenotype at the restrictive temperature (37 degrees C). Cultures of Mc 2 and 3 incubated at the restrictive temperature showed rapid reductions in the percentage of budded cells in the population. In contrast, budding continued for several generations in cultures of Mc 1. Incubation of cultures of Mc 2 and 3 at the restrictive temperature for 48 h resulted in nearly total conversion of yeastlike cells to the multicellular form; about 50% of the cells of Mc 1 had converted to multicellular forms after 48 h at the restrictive temperature. Studies using radiolabeled compounds documented that DNA, RNA, and protein synthesis continued at the restrictive temperature. The results suggest that multicellularity is the result of inhibition of bud emergence and cell separation without inhibition of growth nuclear division, and cytokinesis.     

A probe into nuclear events during the cell cycle of Saccharomyces cerevisiae: studies of folded chromosomes in cdc mutants which arrest in G1

The sedimentation behavior of folded chromosomes from celldivision-cycle (cdc) mutants which arrest in g ₁ was examined. At the restrictive temperature the folded genome of cdc 7, which arrests after spindle pole body (SPB) separation and spindle formation, cosediments with a standard g ₁ structure, indicating that by the cdc 7 step the g ₁ form of the folded genome has been assembled. In the mutant, cdc 4, which arrests before SPB separation but after SPB duplication, a standard g ₁ structure is not formed, cdc 4 cells, however, are able to enter G₀ at the restrictive temperature, and the corresponding g ₀ structure is stable. These results indicate that the cdc 4 gene product may be involved in the development of folded genome conformation which leads to the g ₁ structure. Since the cdc 4 gene product is required for SPB separation, the g ₁ structure may be defined by an association between chromosomes and spindle components. The folded chromosomes of the start mutants cdc 25 and cdc 28 are unstable at the restrictive temperature. In contrast to cdc 4, neither cdc 25 nor cdc 28 are able to enter the G₀ stage in a normal manner, i.e., the g ₀ structure is unstable at the restrictive temperature. The inference is that both the cdc 25 and cdc 28 gene products are required for the functional integrity of the folded genome at both a stage early in G₁ and in the pathway to G₀.     

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.     

Mitochondrial DNA synthesis in cell cycle mutants of saccharomyces cerevisiae

Mitochondrial DNA replication was examined in mutants for seven different Saccharomyces cerevisiae genes which are essential for nuclear DNA replication. In cdc8 and cdc21, mutants defective in continued replication during the S phase of the cell cycle, mitochondrial DNA replication ceases at the nonpermissive temperature. Replication is temperature sensitive even when these mutants are arrested in the G1 phase of the cell cycle with α factor, a condition where mitochondrial DNA replication continues for the equivalent of several generations at the permissive temperature. Therefore the cessation of replication results from a defect in mitochondrial replication per se, rather than from an indirect consequence of cells being blocked in a phase of the cell cycle where mitochondrial DNA is not normally synthesized. Since the temperature-sensitive mutations are recessive, the products of genes cdc8 and cdc21 must be required for both nuclear and mitochondrial DNA replication. In contrast to cdc8 and cdc21, mitochondrial DNA replication continues for a long time at the nonpermissive temperature in five other cell division cycle mutants in which nuclear DNA synthesis ceases within one cell cycle: cdc4, cdc7, and cdc28, which are defective in the initiation of nuclear DNA synthesis, and cdc14 and cdc23, which are defective in nuclear division. The products of these genes, therefore, are apparently not required for the initiation of mitochondrial DNA replication.     

The effect of the cdc9 mutation on premeiotic DNA synthesis in the yeast Saccharomyces cerevisiae

A diploid homozygous for cdc9, a conditional mutation defective in DNA ligase [2], has been used to investigate the role of this enzyme in premeiotic DNA synthesis. The cdc9 ligase has the same effect on premeiotic as on mitotic DNA synthesis and at the restrictive temperature the newly synthesized DNA is recovered in small fragments. A difference has been observed, however, between meiotic and mitotic cells, namely in their ability to join together these fragments on return to the permissive temperature. In mitotic cells this can be readly demonstrated within 50 min, whereas in contrast little joining was detected in meiotic cells, even after 2 h at the permissive temperature.     

The possible functional significance of phosphatidylinositol in G1 arrest of Saccharomyces cerevisiae

Individual phospholipids were assayed in exponentially growing and G₁-arrested temperature-sensitive cell division cycle (cdc) mutants of Saccharomyces cerevisiae. It was observed that cdc28 cells which are known to arrest at ‘start’ when shifted to their non-permissive temperature, resulted in a 40% decrease in phosphatidylinositol (PI) level while the phosphatidylserine (PS) content was doubled in these cells. The reduced level of PI was restored in cdc4 and cdc7 mutants which are known to arrest past the ‘start’. The increase in PS level in cdc8 mutant which was probably to compensate the intrinsic charging of membrane environment, was also reduced in cdc4 and cdc7 mutants. Our results demonstrate that PI may play a role in yeast cell division and growth that the abnormalities of cdc28 could also be related to PI decrease.     

Genetic and enzymatic characterization of conditional lethal mutants of the yeast Schizosaccharomyces pombe with a temperature-sensitive DNA ligase.

The DNA ligase activities of wild type and temperature-sensitive lethal cdc 17 mutants of Schizosaccharomyces pombe have been studied by measuring effects on the conversion of relaxed DNA circles containing a single nick to a closed circular form. Such assays have revealed that all cdc 17 mutants have a thermosensitive DNA ligase deficiency, that this deficiency cosegregates 2:2 with their temperature-sensitive cdc-lethality in three tetrads derived from a cross against wild type, and that genetic reversion of the temperature-sensitive cdc^? phenotype is accompanied by a restoration of DNA ligase activity; all of which implies that the temperature-sensitive cdc^? phenotype of cdc 17 mutants is due to a single nuclear mutation causing a DNA ligase deficiency. Both wild type and mutant enzymes have been partially purified by chromatography in heparin/agarose columns. The wild-type enzyme is completely stable in vitro at both permissive (25 °C) and restrictive (35 °C) temperatures, whereas that of two different mutants, though completely stable at 25 °C, is rapidly inactivated at 35 °C, implying that their mutations are located in the structural gene for DNA ligase.     

The Role of S. CEREVISIAE Cell Division Cycle Genes in Nuclear Fusion

Forty temperature-sensitive cell division cycle (cdc) mutants of Saccharomyces cerevisiae were examined for their ability to complete nuclear fusion during conjugation in crosses to a CDC parent strain at the restrictive temperature. Most of the cdc mutant alleles behaved as the CDC parent strain from which they were derived, in that zygotes produced predominantly diploid progeny with only a small fraction of zygotes giving rise to haploid progeny (cytoductants) that signalled a failure in nuclear fusion. However, cdc4 mutants exhibited a strong nuclear fusion (karyogamy) defect in crosses to a CDC parent and cdc28, cdc34 and cdc37 mutants exhibited a weak karyogamy defect. For all four mutants, the karyogamy defect and the cell cycle defect cosegregated, suggesting that both defects resulted from a single lesion for each of these cdc mutants. Therefore, the cdc 4, 28, 34 and 37 gene products are required in both cell division and karyogamy.     

Initiation of meiosis in cell cycle initiation mutants of Saccharomyces cerevisiae

Control of the initiation of meiosis in yeast was examined in diploids homozygous for one of four different temperature-sensitive mutations that affect “start” of the mitotic cell cycle. Two of the mutations, cdc28 and tra3, bring about deficiencies in the initiation of meiosis, while cdc25 and cdc35 do not prevent initiation of normal meiosis at both permissive and restrictive temperatures. Moreover, diploids homozygous for the latter two mutations are capable of initiating meiosis in rich growth media upon transfer to the high, non-permissive temperature. This unique feature contrasts with the behavior of other yeast strains which require a starvation sporulation medium for initiation of meiosis. It is suggested that the initiation of meiosis includes functions that are shared with “start” of the mitotic cell cycle, as well as functions related to the choice between the two processes. Meiosis in vegetative media at the restrictive temperature (in cdc25 or cdc35 homozygotes) may be important for the study of chemical and physiological phenomena resulting from the meiotic process and not from adaptation to the sporulation medium.     

Sequential gene function in the initiation of Saccharomyces cerevisiae DNA synthesis

Four steps are known to be required for the initiation of DNA synthesis in Saccharomyces cerevisiae. Three of these are mediated by the products of genes cdc 4, 7, and 28 and the fourth is identified by the inhibition exerted on haploid α cells by the mating pheromone, α factor. These four steps have been ordered by a combination of two methods and found to be:

initiation of DNA synthesis The two sequencing methods are described in detail. Experiments involving the shift of mutant cells from the restrictive to the permissive temperature in the presence of cycloheximide demonstrated that the protein synthesis requirement for yeast DNA replication can be completed before the cdc 7-mediated step.     

Msb1 Interacts with Cdc42, Boi1, and Boi2 and May Coordinate Cdc42 and Rho1 Functions during Early Stage of Bud Development in Budding Yeast

Msb1 is not essential for growth in the budding yeast Saccharomyces cerevisiae since msb1Δ cells do not display obvious phenotypes. Genetic studies suggest that Msb1 positively regulates Cdc42 function during bud development, since high-copy MSB1 suppressed the growth defect of temperature-sensitive cdc24 and cdc42 mutants at restrictive temperature, while deletion of MSB1 showed synthetic lethality with cdc24, bem1, and bem2 mutations. However, the mechanism of how Msb1 regulates Cdc42 function remains poorly understood. Here, we show that Msb1 localizes to sites of polarized growth during bud development and interacts with Cdc42 in the cells. In addition, Msb1 interacts with Boi1 and Boi2, two scaffold proteins that also interact with Cdc42 and Bem1. These findings suggest that Msb1 may positively regulate Cdc42 function by interacting with Cdc42, Boi1, and Boi2, which may promote the efficient assembly of Cdc42, Cdc24, and other proteins into a functional complex. We also show that Msb1 interacts with Rho1 in the cells and Msb1 overproduction inhibits the growth of rho1-104 and rho1-3 but not rho1-2 cells. The growth inhibition appears to result from the down-regulation of Rho1 function in glucan synthesis, specifically during early stage of bud development. These results suggest that Msb1 may coordinate Cdc42 and Rho1 functions during early stage of bud development by promoting Cdc42 function and inhibiting Rho1 function. Msb1 overproduction also affects cell morphology, septin organization, and causes increased, aberrant deposition of 1,3-β-glucan and chitin at the mother-bud neck. However, the stimulation of glucan synthesis mainly occurs during late, but not early, stage of bud development.     

Meiotic effects of DNA-defective cell division cycle mutations of Saccharomyces cerevisiae

The meiotic effects of several cell division cycle (cdc) mutations of Saccharomyces cerevisiae have been investigated by electron microscopy and by genetic and biochemical methods. Diploid strains homozygous for cdc mutations known to confer defects on vegetative DNA synthesis were subjected to restrictive conditions during meiosis. Electron microscopy revealed that all four mutants were conditionally arrested in meiosis after duplication of the spindle pole bodies but before spindle formation for the first meiotic division. None of these mutants became committed to recombination or contained synaptonemal complex at the meiotic arrest. — The mutants differed in their ability to undergo premeiotic DNA synthesis under restrictive conditions. Both cdc8 and cdc21, which are defective in the propagation of vegetative DNA synthesis, also failed to undergo premeiotic DNA synthesis. The arrest of these mutants at the stage before meiosis I spindle formation could be attributed to the failure of DNA synthesis because inhibition of synthesis by hydroxyurea also caused arrest at this stage. — Premeiotic DNA synthesis occurred before the arrest of cdc7, which is defective in the initiation of vegetative DNA synthesis, and of cdc2, which synthesizes vegetative DNA but does so defectively. The meiotic arrest of cdc7 homozygotes was partially reversible. Even if further semiconservative DNA replication was inhibited by the addition of hydroxyurea, released cells rapidly underwent commitment to recombination and formation of synaptonemal complexes. The cdc7 homozygote is therefore reversibly arrested in meiosis after DNA replication, whereas vegetative cultures have previously been shown to be defective only in the initiation of DNA synthesis.     

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.     

Isolation, characterisation and molecular cloning of new mutant alleles of the fission yeast p34cdc2+ protein kinase gene: identification of temperature-sensitive G2-arresting alleles

Summary The protein serine-threonine kinase p34 ^cdc2+ plays a central role in the control of the mitotic cell cycle of the fission yeast Schizosaccharomyces pombe. p34 ^cdc2+ function is required both for the initiation of DNA replication and for entry into mitosis, and is also required for the initiation of the second meiotic nuclear division. Recent extensive analysis of p34 ^cdc2+ homologue proteins in higher eukaryotes has demonstrated that p34 ^cdc2+ function is likely to be conserved in all eukaryotic cells. Here we report the isolation and characterisation of five new temperature-sensitive alleles of the cdc ²⁺ gene. All five have been cloned and sequenced, together with the meiotically defective cdc2-N22 allele, bringing the total of p34 ^cdc2+ mutants cloned in this and previous reports to seventeen. The five temperature-sensitive alleles define four separate mutations within the p34 ^cdc2+ protein sequence, two of which give rise to cell cycle arrest in G₂ only, when shifted to the restrictive temperature. The nature of the mutation in each protein is described and possible implications for the structure and function of p34 ^cdc2+ discussed.     

Ethanol-hypersensitive and ethanol-dependent cdc − mutants in Schizosaccharomyces pombe

Ethanol-hypersensitive strains (ets mutants), unable to grow on media containing 6% ethanol, were isolated from a sample of mutagenized Schizosaccharomyces pombe wild-type cells. Genetic analysis of these ets strains demonstrated that the ets phenotype is associated with mutations in a large set of genes, including cell division cycle (cdc) genes, largely non-overlapping with the set represented by the temperature conditional method; accordingly, we isolated some ets non-ts cdc ^? mutants, which may identify novel essential genes required for regulation of the S. pombe cell cycle. Conversely, seven well characterized ts cdc ^? mutants were tested for their ethanol sensitivity; among them, cdc1–7 and cdc13–117 exhibited a tight ets phenotype. Ethanol sensitivity was also tested in strains bearing different alleles of the cdc2 gene, and we found that some of them were ets, but others were non-ets; thus, ethanol hypersensitivity is an allele-specific phenotype. Based on the single base changes found in each particular allele of the cdc2 gene, it is shown that a single amino acid substitution in the p34^cdc2 gene product can produce this ets phenotype, and that ethanol hypersensitivity is probably due to the influence of this alcohol on the secondary and/or tertiary structure of the target protein. Ethanol-dependent (etd) mutants were also identified as mutants that can only be propagated on ethanol-containing media. This novel type of conditional phenotype also covers many unrelated genes. One of these etd mutants, etd1-1, was further characterized because of the lethal cdc ^? phenotype of the mutant cells under restrictive conditions (absence of ethanol). The isolation of extragenic suppressors of etd1-1, and the complementation cloning of a DNA fragment encompassing the etd1 ⁺ wild-type gene (or an extragenic multicopy suppressor) demonstrate that current genetic techniques may be applied to mutants isolated by using ethanol as a selective agent.