Two Cell Division Cycle Mutants of SACCHAROMYCES CEREVISIAE Are Defective in Transmission of Mitochondria to Zygotes

Mutations in CDC genes of S. cerevisiae disrupt the cell cycle at specific stages. The experiments reported here demonstrate that two CDC genes, CDC5 and CDC27, are necessary for mitochondrial segregation as well as for nuclear division. The defect in the transmission of mitochondria was revealed by the examination of uninucleate and binucleate progeny of transient heterokaryons generated by using the kar1-1 mutation that disrupts nuclear fusion. One of the parents lacked mitochondrial DNA (ρ⁰) whereas the other parent had functional mitochondria (ρ⁺). When the parents of the heterokaryon were both wild-type (CDC), nearly all progeny received mitochondria at 21° and at 34°. Thirty-four of the 36 cdc mutations tested had no defect in transmission of mitochondria to zygotic progeny in crosses in which one parent was a cdc mutant and the other parent was not (CDC). However, the cdc5 and cdc27 mutations prevented the transmission of mitochondria to cdc progeny at 34° but not at 21°; CDC progeny received mitochondria at either temperature. This defect was observed in crosses of cdc5 or cdc27 by wild-type cells regardless of which parent donated mitochondria to the zygote. The defect in mitochondrial transmission cosegregated in meiotic tetrads with the defect in mitosis demonstrating that both are likely to be caused by the same temperature-sensitive mutation. These results indicate that the CDC5 and CDC27 gene products are essential in two motility-related processes: mitochondrial movement from the zygote to the progeny and in mitosis.—Furthermore, the results suggest that the function performed by the CDC5 and CDC27 gene products for mitochondrial transmission differ in some fundamental way from the function performed for mitosis. The function necessary for mitosis can be supplied to the cdc5 (or cdc27) nucleus by the CDC5 (or CDC27) nucleus in the same heterokaryon but the function necessary for mitochondrial transmission cannot. Perhaps the function needed for mitochondrial transmission must be performed in the cell cycle preceding the actual segregation of mitochondria whereas the function needed for nuclear segregation can be performed at the time that mitosis occurs.     

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.     

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.     

Test for temporal or spatial restrictions in gene product function during the cell division cycle.

The ability of a functional gene to complement a nonfunctional gene may depend upon the intracellular relationship of the two genes. If so, the function of the gene product in question must be limited in time or in space. CDC (cell division cycle) gene products of Saccharomyces cerevisiae control discrete steps in cell division; therefore, they constitute reasonable candidates for genes that function with temporal or spatial restrictions. In an attempt to reveal such restrictions, we compared the ability of a CDC gene to complement a temperature-sensitive cdc gene in diploids where the genes are located within the same nucleus to complementation in heterokaryons where the genes are located in different nuclei. In CDC X cdc matings, complementation was monitored in rare heterokaryons by assaying the production of cdc haploid progeny (cytoductants) at the restrictive temperature. The production of cdc cytoductants indicates that the cdc nucleus was able to complete cell division at the restrictive temperature and implies that the CDC gene product was provided by the other nucleus or by cytoplasm in the heterokaryon. Cytoductants from cdc28 or cdc37 crosses were not efficiently produced, suggesting that these two genes are restricted spatially or temporally in their function. We found that of the cdc mutants tested 33 were complemented; cdc cytoductants were recovered at least as frequently as CDC cytoductants. A particularly interesting example was provided by the CDC4 gene. Mutations in CDC4 were found previously to produce a defect in both cell division and karyogamy. Surprisingly, the cell division defect of cdc4 nuclei is complemented by CDC4 nuclei in a heterokaryon, whereas the karyogamy defect is not.     

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.     

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.     

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.     

“Start” Mutants of Saccharomyces cerevisiae Are Suppressed in Carbon Catabolite-Derepressing Medium

Temperature-sensitive cell division “start” mutants cdc28, cdc36, cdc37, and cdc39 of the yeast Saccharomyces cerevisiae arrested cell division in the G1 phase of the cell cycle in glucose medium. I report here that cdc28, cdc36, and cdc39 mutants were suppressed when grown in carbon catabolite-derepressing medium.     

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.     

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.     

A change in sister chromatid behavior precedes nuclear division in Saccharomyces cerevisiae

We used a genetic assay to monitor the behavior of sister chromatids during the cell cycle. We show that the ability to induce sister chromatid exchanges (SCE) with ionizing radiation is maximal in budded cells with undivided nuclei and then decreases prior to nuclear division. SCE can be induced in cells arrested in G2 using either nocodazole or cdc mutants. These data show that sister chromatids have two different states prior to nuclear division. We suggest that the sister chromatids of cir. III, a circular derivative of chromosome III, separate (anaphase A) prior to spindle elongation (anaphase B). Other interpretations are also discussed. SCE can be induced in cdc mutants that arrest in G2 and in nocodazole-treated cells, suggesting that mitotic checkpoints arrest cells prior to sister chromatid separation.     

The plant cell cycle

The first aim of this paper is to review recent progress in identifying genes in plants homologous to cell division cycle (cdc) genes of fission yeast. In the latter, cdc genes are well-characterised. Arguably, most is known about cdc2 which encodes a 34 kDa protein kinase (p34^cdc2) that functions at the G2-M and G1-S transition points of the cell cycle. At G2-M, the p34^cdc2 protein kinase is regulated by a number of gene products that function in independent regulatory pathways. The cdc2 kinase is switched on by a phosphatase encoded by cdc25, and switched off by a protein kinase encoded by weel. p34 Must also bind with a cyclin protein to form maturation promoting factor before exhibiting protein kinase activity. In plants, homologues to p34^cdc2 have been identified in pea, wheat, Arabidopsis, alfalfa, maize and Chlamydomonas. They all exhibit the PSTAIRE motif, an absolutely conserved amino acid sequence in all functional homologues sequenced so far. As in animals, some plant species contain more than one cdc2 protein kinase gene. but in contrast to animals where one functions at G2-M and the other (CDK2 in humans and Egl in Xenopus) at G1-S, it is still unclear whether there are functional differences between the plant p34^cdc2 protein kinases. Again, whereas in animals cyclins are well characterised on the basis of sequence analysis, into class A, class B (G2-M) and CLN (G1 cyclins), cyclins isolated from several plant species cannot be so clearly characterised. The differences between plant and animal homologues to p34^cdc2 and cyclins raises the possibility that some of the regulatory controls of the plant genes may be different from those of their animal counterparts. The second aim of the paper is to review how planes of cell division and cell size are regulated at the molecular level. We focus on reports showing that p34^cdc2 binds to the preprophase band (ppb) in late G2 of the cell cycle. The binding of p34^cdc2 to ppbs may be important in regulating changes in directional growth but, more importantly, there is a requirement to understand what controls the positioning of ppbs. Thus, we highlight work resolving proteins such as the microtubule associated proteins (MAPs) and those mitogen activated protein kinases (MAP kinases), which act on, or bind to, mitotic microtubules. Plant homologues to MAP kinases have been identified in alfalfa. Finally, some consideration is given to cell size at division and how alterations in cell size can alter plant development. Transgenic tobacco plants expressing the fission yeast gene, cdc25, exhibited various perturbations of development and a reduced cell size at division. Hence, cdc25 affected the cell cycle (and as a consequence, cell size at division) and cdc25 expression was correlated with various alterations to development including precocious flowering and altered floral morphogenesis. Our view is that the cell cycle is a growth cycle in which a cell achieves an optimal size for division and that this size control has an important bearing on differentiation and development. Understanding how cell size is controlled, and how plant cdc genes are regulated, will be essential keys to ‘the cell cycle locks’, which when ‘opened’, will provide further clues about how the cell cycle is linked to plant development.     

Genetic control of the cell division cycle in yeast. IV. Genes controlling bud emergence and cytokinesis

Temperature-sensitive mutations in one gene (cdc1) of Saccharomyces cerevisiae confer a defect in bud emergence. Asynchronous cultures of cells defective in cdc1 collect uniformly as unbudded cells (or cells with very tiny buds) following a shift from the permissive to the restrictive temperature. Studies with synchronous cultures demonstrate that the thermolabile product of cdc1 completes its function (the execution point) for bud emergence at the time of bud emergence (0.2 fractions of a cell cycle). When this function is not completed at the restrictive temperature. cells complete DNA replication but do not undergo nuclear division.     

The Selection of S. CEREVISIAE Mutants Defective in the Start Event of Cell Division

Thirty-three temperature-sensitive mutations defective in the start event of the cell division cycle of Saccharomyces cerevisiae were isolated and subjected to preliminary characterization. Complementation studies assigned these mutations to four complementation groups, one of which, cdc28, has been described previously. Genetic analysis revealed that these complementation groups define single nuclear genes, unlinked to one another. One of the three newly identified genes, cdc37, has been located in the yeast linkage map on chromosome IV, two meiotic map units distal to hom2.—Each mutation produces stage-specific arrest of cell division at start, the same point where mating pheromone interrupts division. After synchronization at start by incubation at the restrictive temperature, the mutants retain the capacity to enlarge and to conjugate.     

Regulation of mating in the cell cycle of Saccharomyces cerevisiae

The capacity of haploid a yeast cells to mate (fuse with a haploid strain of alpha mating type followed by nuclear fusion to produce a diploid cell) was assessed for a variety of temperature-sensitive cell division cycle (cdc) mutants at the permissive and restrictive temperatures. Asynchronous populations of some mutants do not mate at the restrictive temperature, and these mutants define genes (cdc 1, 4, 24, and 33) that are essential both for the cell cycle and for mating. For most cdc mutants, asynchronous populations mate well at the restrictive temperature while populations synchronized at the cdc block do not. Populations of a mutant carrying the cdc 28 mutation mate well at the restrictive temperature after synchronization at the cdc 28 step. These results suggest that mating can occur from the cdc 28 step, the same step at which mating factors arrest cell cycle progress. The cell cycle interval in which mating can occur may or may not extend to the immediately succeeding and diverging steps (cdc 4 and cdc 24). High frequency mating does not occur in the interval of the cell cycle extending from the step before the initiation of DNA synthesis (cdc 7) through DNA synthesis (cdc 2, 8, and 21), medial nuclear division (cdc 13), and late nuclear division (cdc 14 and 15).     

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.

     

Interdependence of cell cycle events inSchizosaccharomyces pombe. Terminal phenotypes of cell division cycle mutants arrested during dna synthesis and nuclear division

Summary Temperature-sensitive cell division cycle (cdc) mutants of the fission yeastSchizosaccharomyces pombe, previously characterized as defective in nuclear division were examined by thin section electron microscopy. All of the mutants failed to enter mitosis, rather they accumulated at one of four distinct terminal phenotypes. Class one were arrested with a nucleus rectangular in cross-section and a laterally situated spindle pole body (SPB). The second group had spherical or rectangular nuclei with a single SPB. The sole member of the third group wascdc 27. K 3, which had a spherical crenated nucleus with a single SPB from which microtubules emerged and extended into the cytoplasm. Allelic variants ofcdc 25 comprised the fourth group all of which displayed aberrant nuclear morphologies. Utilizing this ultrastructural data together with a knowledge of the transition points of these mutants a model for the interdependence of certain cell cycle event is proposed in which the initiation of DNA synthesis is uncoupled from the replication and separation of the SPB. This paper also provides new information on SPB structure inS. pombe. This is discussed in connection with the transient assembly of both spindle and cytoplasmic microtubules.     

Molecular Cloning and Characterization of a cDNA Clone That Encodes a Cdc2 Homolog from Nicotiana tabacum

We have isolated a cDNA clone (cdc2Nt1) that encodes a homologof p34^cdc2/CDC28 kinase from tobacco (Nicotiana tabacum). Thecdc2Ntl protein showed extensive similarity to other homologsof Cdc2 from plants. Complementation studies showed that thecdc2Ntl gene was able to overcome cell cycle arrest at boththe G1/S and the G2/M transitions of cdc28^ts mutants of buddingyeast, demonstrating that the cdc2Ntl protein was able to replacethe Cdc28 kinase at both the G1/S and the G2/M transitions.Analysis of gene expression demonstrated that the cdc2Ntl genewas transcribed constitutively throughout the cell cycle butthat it was preferentially expressed in actively dividing tobaccoBY-2 cells. (Received July 13, 1995; Accepted February 15, 1996)