The budding yeast U5 snRNP Prp8 is a highly conserved protein which links RNA splicing with cell cycle progression.

The dbf3 mutation was originally obtained in a screen for DNA synthesis mutants with a cell cycle phenotype in the budding yeast Saccharomyces cerevisiae. We have now isolated the DBF3 gene and found it to be an essential gene with an ORF of 7239 nucleotides, potentially encoding a large protein of 268 kDa. We also obtained an allele-specific high copy number suppressor of the dbf3-1 allele, encoded by the known SSB1 gene, a member of the Hsp70 family of heat shock proteins. The sequence of the Dbf3 protein is 58% identical over 2300 amino acid residues to a predicted protein from Caenorhabditis elegans. Furthermore, partial sequences with 61% amino acid sequence identity were deduced from two files of human cDNA in the EST nucleotide database so that Dbf3 is a highly conserved protein. The nucleotide sequence of DBF3 turned out to be identical to the yeast gene PRP8, which encodes a U5 snRNP required for pre-mRNA splicing. This surprising result led us to further characterise the phenotype of dbf3 which confirmed its role in the cell cycle and showed it to function early, around the time of S phase. This data suggests a hitherto unexpected link between pre-mRNA splicing and the cell cycle.     

Temperature-Sensitive Cdc 7 Mutations of Saccharomyces Cerevisiae Are Suppressed by the Dbf4 Gene, Which Is Required for the G(1)/S Cell Cycle Transition

When present on a multicopy plasmid, a gene from a Saccharomyces cerevisiae genomic library suppresses the temperature-sensitive cdc7-1 mutation. The gene was identified as DBF4, which was previously isolated by complementation in dbf4-1 mutant cells and is required for the G1----S phase progression of the cell cycle. DBF4 has an open reading frame encoding 695 amino acid residues and the predicted molecular mass of the gene product is 80 kD. The suppression is allele-specific because a CDC7 deletion is not suppressed by DBF4. Suppression is mitosis-specific and the sporulation defect of cdc7 mutations is not suppressed by DBF4. Conversely, CDC7 on a multicopy plasmid suppresses the dbf4-1, -2, -3 and -4 mutations but not dbf4-5 and DBF4 deletion mutations. Furthermore, cdc7 mutations are incompatible with the temperature-sensitive dbf4 mutations. These results suggest that the CDC7 and DBF4 polypeptides interact directly or indirectly to permit initiation of yeast chromosome replication.     

Cloning and characterization of the nuclear AC115 gene of Chlamydomonas reinhardtii

The nuclear ac115 mutant of Chlamydomonas reinhardtii is specifically blocked in the synthesis of the chloroplast encoded D2 protein of the photosystem II reaction center at a point after translation initiation. Here, we report the identification of the AC115 gene through complementation rescue of the ac115 mutant strain, using an indexed cosmid library of Chlamydomonas genomic DNA. AC115 is a small, novel, intronless nuclear gene which encodes a protein of 113 amino acids. The amino terminal end of the Ac115 protein is rich in basic amino acids and has features which resemble a chloroplast transit sequence. A hydrophobic stretch of amino acids at the protein's carboxyl terminus is sufficiently large to be a membrane spanning or a protein/protein interaction domain. Various models are discussed to account for the mechanism by which Ac115p works in D2 synthesis. The ac115 mutant allele was sequenced and determined to be an A-to-T transversion at the first position of the fourth codon of the coding sequence. This mutation changes an AAG codon to a TAG nonsense codon and results in a null phenotype.     

Nuclear division cycle in germinating conidia of Neurospora crassa.

A temperature-sensitive mutant has been shown to be blocked at a specific point in the nuclear division cycle: just before the initiation of DNA synthesis at the time when the spindle pole bodies have duplicated but not separated. The metabolic activities of conidia of this mutant strain at the nonpermissive temperature have led us to conclude that the nuclei in a population of dormant conidia are arrested at various points in the nuclear division cycle. This conclusion is substantiated by the activities of conidia in the presence of the inhibitory drugs cycloheximide and hydroxyurea. In each inhibitory situation we observed that some, but not all, of the conidia were able to accomplish DNA synthesis and/or nuclear division.     

SPO12 and SIT4 suppress mutations in DBF2, which encodes a cell cycle protein kinase that is periodically expressed.

To help clarify the role of DBF2, a previously described cell cycle protein kinase, high copy number suppressors of the dbf2 mutation were isolated. Three open reading frames (ORF) have been identified. One ORF encodes a protein which has homology to a human small nuclear riboprotein, while the remaining two are genes which have been identified previously, SIT4 and SPO12. SIT4 is known to have a role in the cell cycle but the nature of the interaction between SIT4 and dbf2 is unclear. SPO12 has until now been implicated exclusively in meiosis. However, we show that SPO12 is expressed during vegetative growth, moreover it is expressed under cell cycle control coordinately with DBF2. SPO12 is a nonessential gene, but it becomes essential in a DBF2 delete genetic background. Furthermore, detailed analysis of the cell cycle of SPO12 delete cells revealed a small but significant delay in mitosis. Therefore, SPO12 does have a role during vegetative growth and it probably functions in mitosis in association with DBF2.     

Segregation of unreplicated chromosomes in Saccharomyces cerevisiae reveals a novel G1/M-phase checkpoint.

Saccharomyces cerevisiae dbf4 and cdc7 cell cycle mutants block initiation of DNA synthesis (i.e., are iDS mutants) at 37 degrees C and arrest the cell cycle with a 1C DNA content. Surprisingly, certain dbf4 and cdc7 strains divide their chromatin at 37 degrees C. We found that the activation of the Cdc28 mitotic protein kinase and the Dbf2 kinase occurred with the correct relative timing with respect to each other and the observed division of the unreplicated chromatin. Furthermore, the division of unreplicated chromatin depended on a functional spindle. Therefore, the observed nuclear division resembled a normal mitosis, suggesting that S. cerevisiae commits to M phase in late G1 independently of S phase. Genetic analysis of dbf4 and cdc7 strains showed that the ability to restrain mitosis during a late G1 block depended on the genetic background of the strain concerned, since the dbf4 and cdc7 alleles examined showed the expected mitotic restraint in other backgrounds. This restraint was genetically dominant to lack of restraint, indicating that an active arrest mechanism, or checkpoint, was involved. However, none of the previously described mitotic checkpoint pathways were defective in the iDS strains that carry out mitosis without replicated DNA, therefore indicating that the checkpoint pathway that arrests mitosis in iDS mutants is novel. Thus, spontaneous strain differences have revealed that S. cerevisiae commits itself to mitosis in late G1 independently of entry into S phase and that a novel checkpoint mechanism can restrain mitosis if cells are blocked in late G1. We refer to this as the G1/M-phase checkpoint since it acts in G1 to restrain mitosis.     

Caulobacter crescentus fatty acid-dependent cell cycle mutant.

A fatty acid auxotroph of Caulobacter crescentus, AE6001, which displays a strict requirement for unsaturated fatty acids to grow on glucose as the carbon source has been isolated. Starvation of AE6001 for unsaturated fatty acids resulted in a block in the cell cycle. Starved cultures accumulated at the predivisional cell stage after a round of DNA replication had been completed and after a flagellum had been assembled at the pole of the cell. Cell division and cell growth failed to occur probably because the mutant was unable to synthesize a membrane. An analysis of double mutants containing the fatB503 allele and other mutations in membrane biogenesis demonstrated that the cell cycle of AE6001 blocked at a homeostatic state. The addition of oleic acid to starved cultures permitted cell division and the initiation of a new round of DNA replication. The coincident block in both the initiation of DNA replication and membrane assembly, exhibited by starved cultures of this mutant, suggests that the fatB503 gene product may be involved in the coordination of these events.     

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).     

A set of ftsZ mutants blocked at different stages of cell division in Caulobacter

FtsZ is required throughout the cell division process in eubacteria and in archaea. We report the isolation of novel mutants of the FtsZ gene in Caulobacter crescentus. Clusters of charged amino acids were changed to alanine to minimize mutations that affect protein folding. Molecular modelling indicated that all the clustered-charged-to-alanine mutations had altered amino acids at the surface of the protein. Of 13 such mutants, four were recessive-lethal, three were dominant-lethal, and six had no discernible phenotype. An FtsZ depletion strain of Caulobacter was constructed to analyse the phenotype of the recessive-lethal mutations and used to show that they blocked cell division at distinct stages. One mutation blocked the initiation of cell division, two mutations blocked cell division randomly, and one mutation blocked both early and late stages of cell division. The effect of the recessive mutations on the subcellular localization of FtsZ was determined. Models to explain the various mutant phenotypes are discussed. This is the first set of recessive alleles of ftsZ blocked at different stages of cell division.     

Regulation of cell cycle events in asymmetrically dividing cells: functions required for DNA initiation and chain elongation in Caulobacter crescentus

To study the regulation of cell cycle events after asymmetric cell division in Caulobacter crescentus, we have identified functions that are required for DNA synthesis in the stalked cell produced at division and in the new stalked cell that develops from the swarmer cell 60 min after division. The initiation of DNA synthesis in the two progeny cells is dependent upon at least two common functions. One of these is a requirement for protein synthesis and the other is a gene product identified in a temperature-sensitive cell cycle mutant. DNA chain elongation requires a third common function. The characteristic pattern of DNA synthesis in C. crescentus appears to be controlled in part by the expression of these functions in the two stalked cells at different times after cell division. The age distribution for Caulobacter cells in an exponential population has been calculated (Appendix by Robert Tax) and used to analyze some of the results.     

Spo12 Is a Limiting Factor That Interacts with the Cell Cycle Protein Kinases Dbf2 and Dbf20, Which Are Involved in Mitotic Chromatid Disjunction

The DBF2 and DBF20 genes of the budding yeast Saccharomyces cerevisiae encode a pair of structurally similar protein kinases. Although yeast with either gene deleted is viable, deletion of both genes is lethal. Thus, the Dbf2 and Dbf20 proteins are functional alternatives for an essential activity. In contrast to deletions, four different mutant alleles of DBF2 are lethal. Thus, the presence of a nonfunctional Dbf2 protein, rather than the lack of function per se, is inhibitory. Here we present genetic evidence that nonfunctional mutant Dbf2 protein blocks the function of Dbf20 protein by sequestering a common interacting protein encoded by SPO12. Even a single extra copy of SPO12 is sufficient to suppress the dbf2 defect. Since SPO12 appears to encode a limiting factor, it may be a rate limiting cofactor that is involved in the regulation of the Dbf2 and Dbf20 protein kinases. A corollary to the finding that one extra copy of SPO12 can suppress dbf2, is that the acquisition of an extra chromosome VIII, which carries the SPO12 locus, will also suppress dbf2. Indeed, physical analysis of chromosome copy number in dbf2 revertants able to grow at 37° showed that the frequency of chromosome VIII acquisition increased when cells were incubated at the restrictive temperature, and reached a frequency of more than 100-fold the amount in wild-type yeast. This suggested that the dbf2 mutation was not only suppressed by an extra copy of chromosome VIII but also that the dbf2 mutation actually caused aberrant chromosomal segregation. Conventional assays for chromosome loss confirmed this proposal.     

A novel nucleoskeletal-like protein located at the nuclear periphery is required for the life cycle of Saccharomyces cerevisiae.

In order to study the role of nucleoskeletal components for nuclear and cell division in the budding yeast Saccharomyces cerevisiae, we have employed a combined biochemical/genetic approach. We have identified a peripheral nuclear protein which appears to be located both at the nuclear membrane and the spindle pole body. The gene has been cloned and subsequently shown to be essential for cell growth. The DNA sequence of the gene has been determined. As deduced from the nucleotide sequence, the gene potentially codes for a novel 86 kd protein with a highly repetitive and conserved nine amino acid sequence motive in the middle part of the protein. The flanking amino- and carboxy-terminal regions have similarities to intermediate filaments and calcium binding proteins, respectively. It appears that the 86 kd protein is a regulated nucleoskeletal-like protein (NSP1) involved in the process of nuclear and/or cell division. The affinity-purified antibody against the yeast NSP1 protein stained the nucleus and centrosomes of mammalian MDCK (Madin Darby canine kidney) cells in indirect immunofluorescence.     

A further two mutants defective in initiation of the S phase in the yeastSaccharomyces cerevisiae

Summary Two new mutantsdbf3 and4, are specifically defective in DNA synthesis. When synchronous cultures ofdbf4 were transferred from the permissive to restrictive temperature before the start of the S phase, no DNA synthesis occurred. However when switched after the beginning of DNA replication, the cells completed that round of synthesis.Dbf4 therefore resemblescdc7, a mutant believed to be required for initiation of DNA synthesis, and indeeddbf4 acts at a point in the cell cycle close tocdc7, namely betweencdc4 and the final requirement for protein synthesis before the S phase. Likedbf4, cultures ofdbf3 transferred to restrictive conditions before the start of S showed little DNA synthesis. However a small burst did occur at a time roughly corresponding to when normal initiation would be expected. Cultures switched after this time completed the ongoing round of DNA synthesis.     

Isolation of the human gene that complements a temperature-sensitive cell cycle mutation in BHK cells.

We have cloned the human genomic DNA and the corresponding cDNA for the gene which complements the mutation of tsBN51, a temperature-sensitive (Ts) cell cycle mutant of BHK cells which is blocked in G1 at the nonpermissive temperature. After transfecting human DNA into TsBN51 cells and selecting for growth at 39.5 degrees C, Ts+ transformants were identified by their content of human AluI repetitive DNA sequences. Following two additional rounds of transfection, a genomic library was constructed from a tertiary Ts+ transformant and a recombinant phage containing the complementing gene isolated by screening for human AluI sequences. A genomic probe from this clone recognized a 2-kilobase mRNA in human and tertiary transformant cell lines, and this probe was used to isolate a biologically active cDNA from the Okayama-Berg cDNA expression library. Sequencing of this cDNA revealed a single open reading frame encoding a polypeptide of 395 amino acids. The deduced BN51 gene product has a high proportion of acidic and basic amino acids which are clustered in four hydrophilic domains spaced at 60- to 80-amino-acid intervals. These domains have strong sequence homology to each other. Thus, the tsBN51 protein consists of periodic repetitive clusters of acidic and basic amino acids.     

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.