Identification and Cloning of the Chl4 Gene Controlling Chromosome Segregation in Yeast

A collection of chl mutants characterized by decreased fidelity of chromosome transmission and by minichromosome nondisjunction in mitosis was examined for the ability to maintain nonessential dicentric plasmids. In one of the seven mutants analyzed, chl4, dicentric plasmids did not depress cell division. Moreover, nonessential dicentric plasmids were maintained stably without any rearrangements during many generations in the chl4 mutant. The rate of mitotic heteroallelic recombination in the chl4 mutant was not increased compared to that in an isogenic wild-type strain. Analysis of the segregation of a marked chromosome indicated that sister chromatid nondisjunction and sister chromatid loss contributed equally to chromosome malsegregation in the chl4 mutant. A genomic clone of CHL4 was isolated by complementation of the chl4-1 mutation and was physically mapped to the right arm of chromosome IV near the SUP2 gene. Nucleotide sequence analysis of CHL4 clone revealed a 1.4-kb open reading frame coding for a 53-kD predicted protein which does not have homology to published proteins. A strain containing a null allele of CHL4 is viable under standard growth conditions but has a temperature-sensitive phenotype (conditional lethality at 36°). We suggest that the CHL4 gene is required for kinetochore function in the yeast Saccharomyces cerevisiae.     

The CHL 1 (CTF 1) gene product of Saccharomyces cerevisiae is important for chromosome transmission and normal cell cycle progression in G2/M.

We have analyzed the CTF1 gene, identified in a screen for mutants with decreased chromosome transmission fidelity and shown to correspond to the previously identified chl1 mutation. Chl1 null mutants exhibited a 200-fold increase in the rate of chromosome III missegregation per cell division, and near wild-type rates of marker homozygosis on this chromosome by mitotic recombination. Analysis of the segregation of a marker chromosome indicated that sister chromatid loss (1:0 segregation) and sister chromatid non-disjunction (2:0 segregation) contributed equally to chromosome missegregation. A genomic clone of CHL1 was isolated and used to map its physical position on chromosome XVI. Nucleotide sequence analysis of CHL1 revealed a 2.6 kb open reading frame with a 99 kd predicted protein sequence that contained two PEST sequences and was 23% identical to the coding region of a nucleotide excision repair gene, RAD3. Domains of homology between these two predicted protein sequences included a helix-turn-helix motif and an ATP binding site containing a helicase consensus. Mutants lacking the CHL1 gene product are viable and display two striking, and perhaps interrelated, phenotypes: extreme chromosome instability and a delay in cell cycle progression in G2/M. This delay is independent of the cell cycle checkpoint that requires the function of the RAD9 gene.     

CTF4 (CHL15) mutants exhibit defective DNA metabolism in the yeast Saccharomyces cerevisiae.

We have analyzed the CTF4 (CHL15) gene, earlier identified in two screens for yeast mutants with increased rates of mitotic loss of chromosome III and artificial circular and linear chromosomes. Analysis of the segregation properties of circular minichromosomes and chromosome fragments indicated that sister chromatid loss (1:0 segregation) is the predominant mode of chromosome destabilization in ctf4 mutants, though nondisjunction events (2:0 segregation) also occur at an increased rate. Both inter- and intrachromosomal mitotic recombination levels are elevated in ctf4 mutants, whereas spontaneous mutation to canavanine resistance was not elevated. A genomic clone of CTF4 was isolated and used to map its physical and genetic positions on chromosome XVI. Nucleotide sequence analysis of CTF4 revealed a 2.8-kb open reading frame with a 105-kDa predicted protein sequence. The CTF4 DNA sequence is identical to that of POB1, characterized as a gene encoding a protein that associates in vitro with DNA polymerase alpha. At the N-terminal region of the protein sequence, zinc finger motifs which define potential DNA-binding domains were found. The C-terminal region of the predicted protein displayed similarity to sequences of regulatory proteins known as the helix-loop-helix proteins. Data on the effects of a frameshift mutation suggest that the helix-loop-helix domain is essential for CTF4 function. Analysis of sequences upstream of the CTF4 open reading frame revealed the presence of a hexamer element, ACGCGT, a sequence associated with many DNA metabolism genes in budding yeasts. Disruption of the coding sequence of CTF4 did not result in inviability, indicating that the CTF4 gene is nonessential for mitotic cell division. However, ctf4 mutants exhibit an accumulation of large budded cells with the nucleus in the neck. ctf4 rad52 double mutants grew very slowly and produced extremely high levels (50%) of inviable cell division products compared with either single mutant alone, which is consistent with a role for CTF4 in DNA metabolism.     

The causes of instability of artificial mini-chromosomes in yeasts mutant for chl genes

In mutants chl2, chl3, chl5, and chl6, which control mitotic chromosome transmission, the behaviour of the centromeric plasmids with various genes was analyzed. The main cause of chromosome instability in chl2, chl5, and chl6 is chromosome loss during cell division (1:0 segregation). The main cause of chromosome instability in chl3. is nondisjunction (2:0 segregation). According to this, the chl3 mutant, but not other chl's, cannot maintain the mini-chromosome with SUP11 gene. This gene causes cell death in high copy number. Chromosome nondisjunction in chl3 is also confirmed by the data on the mini-chromosome carrying CUP1 gene responsible for copper-resistance in yeast. The copper resistancy level in chl3 transformants is much higher than in chl5 or wild type transformants. Elevated copper resistance of chl3 transformants is caused by the transit accumulation of CUP1-carrying mini-chromosome in part of the cell population as a result of segregation mistakes upon cell divisions. Thus, the CHL3 gene is a new gene that controls the process of mitotic chromosome disjunction in yeast.     

Structure and function of the Saccharomyces cerevisiae CDC2 gene encoding the large subunit of DNA polymerase III.

Saccharomyces cerevisiae cdc2 mutants arrest in the S-phase of the cell cycle when grown at the non-permissive temperature, implicating this gene product as essential for DNA synthesis. The CDC2 gene has been cloned from a yeast genomic library in vector YEp13 by complementation of a cdc2 mutation. An open reading frame coding for a 1093 amino acid long protein with a calculated mol. wt of 124,518 was determined from the sequence. This putative protein shows significant homology with a class of eukaryotic DNA polymerases exemplified by human DNA polymerase alpha and herpes simplex virus DNA polymerase. Fractionation of extracts from cdc2 strains showed that these mutants lacked both the polymerase and proofreading 3'-5' exonuclease activity of DNA polymerase III, the yeast analog of mammalian DNA polymerase delta. These studies indicate that DNA polymerase III is an essential component of the DNA replication machinery.     

Involvement of cdc13+ in mitotic control in Schizosaccharomyces pombe: possible interaction of the gene product with microtubules.

Previous genetic studies have shown that the fission yeast cdc13+ gene product interacts closely with the cdc2+ protein kinase during mitosis. Here, we have cloned the cdc13+ gene from a S. pombe gene bank by complementation of the temperature-sensitive defect of a cdc13-117 mutant strain. The complementing activity was localized to a 1.9-kb XbaI-NsiI DNA fragment, and nucleotide sequencing revealed a 1446-bp open reading frame. The predicted amino acid sequence contained 482 residues and was not homologous to any protein in a protein database. The cdc13+ gene function was confirmed to be essential for cell division since cells carrying a cdc13 null allele arrested with a cdc phenotype. However, unlike any existing temperature-sensitive cdc13 mutants, cdc13 null mutants arrested in G2 without septa or condensed chromosomes indicating that cdc13+ gene function is required at or prior to the initiation of mitotis. cdc13-117 mutant strains were found to be hypersensitive to the tubulin inhibitor thiabendazole. This observation suggests that the cdc13+ gene product, which is required for mitotic initiation, may interact with microtubules.     

Identification and characterization of yeast mutants and the gene for a cruciform cutting endonuclease.

An assay was developed that detected DNA cruciform cutting endonuclease activity in crude extracts of Saccharomyces cerevisiae. A collection of temperature-sensitive strains was screened using this assay, and a mutant lacking the activity was found. The mutation leading to the enzymatic defect was mapped to the left arm of chromosome XI within 3 cM of the centromere. Cloning of the gene for this endonuclease was achieved by chromosome walking from the nearby PUT3 locus. The gene, called CCE1 (cruciform cutting endonuclease), was sequenced and found to have an open reading frame encoding a 41 kDa protein. The amino acid sequence of this eukaryotic endonuclease shows homology neither to its prokaryotic counterparts nor to other proteins in available databases. A cce1 null mutant has no obvious growth defect, and despite the ability of the CCE1 enzyme to cleave Holliday junction analogs, the mutant shows no defect in meiotic or mitotic recombination. A second cruciform cutting activity was detected in extracts from a cce1 null mutant, indicating that yeast has at least two such enzymes. The only phenotype observed for cce1 mutants is a higher than normal frequency of appearance of petite cells, suggesting that the CCE1 protein is important for the maintenance of mitochondrial DNA.     

A protein kinase gene complements the lytic phenotype of Saccharomyces cerevisiae lyt2 mutants

By genetic analysis of a thermosensitive autolytic mutant whose phenotype was complemented by osmotic stabilization with sorbitol, we identified gene LYT2 of Saccharomyces cerevisiae, which is probably involved in cell wall formation. A yeast gene complementing lyt2 strains was cloned and shown to carry an open reading frame coding for a 484-amino-acid protein exhibiting all the characteristic domains of serine/threonine protein kinases and highly homologous to other yeast protein kinases involved in control of the mitotic cycle. Mutants disrupted in the cloned gene also displayed an autolytic phenotype complemented by osmotic stabilization with sorbitol. However, genetic comparison of lyt2 mutants and disruptants of the protein kinase gene revealed that the cloned gene is not the structural gene LYT2 but a suppressor of the lytic phenotype, named gene SLT2, that was mapped to chromosome V. The product of gene SLT2 is the first protein kinase to be described in relation to the yeast cell-wall functions.     

A hyper-recombination mutation in S. cerevisiae identifies a novel eukaryotic topoisomerase

A hyper-recombination mutation was isolated that causes an increase in recombination between short repeated delta sequences surrounding the SUP4-omicron gene in S. cerevisiae. The wild-type copy of this gene was cloned by complementation of one of its pleiotropic phenotypes, slow growth. DNA sequence of the clone revealed a 656 amino acid open reading frame capable of encoding a protein homologous to the bacterial type I topoisomerase. No homology was detected with previously identified eukaryotic topoisomerases. Construction of double mutants with either of the two known yeast topoisomerase genes revealed synergistic effects on growth suggesting overlapping functions. Expression of bacterial topoisomerase I in yeast can fully complement the slow growth defect of a null mutation. We have named this locus TOP3 and suggest that it defines a novel eukaryotic topoisomerase gene.     

Vaccinia virus encodes an essential gene with strong homology to protein kinases

The B1 gene of vaccinia virus encodes a 34-kDa protein which is essential for viral replication. Temperature-sensitive mutants bearing lesions in this gene arrest at the stage of DNA replication during nonpermissive infections. In this report, the sequence of the 34-kDa open reading frame is presented, and the mutations in two ts alleles are identified. Analysis of the deduced protein sequence reveals strong homology with catalytic domains of numerous protein kinases. The lesion in one of the mutants alters an invariant glycine residue within one such domain.     

CDC44: a putative nucleotide-binding protein required for cell cycle progression that has homology to subunits of replication factor C.

To investigate the means by which a cell regulates the progression of the mitotic cell cycle, we characterized cdc44, a mutation that causes Saccharomyces cerevisiae cells to arrest before mitosis. CDC44 encodes a 96-kDa basic protein with significant homology to a human protein that binds DNA (PO-GA) and to three subunits of human replication factor C (also called activator 1). The hypothesis that Cdc44p is involved in DNA metabolism is supported by the observations that (i) levels of mitotic recombination suggest elevated rates of DNA damage in cdc44 mutants and (ii) the cell cycle arrest observed in cdc44 mutants is alleviated by the DNA damage checkpoint mutations rad9, mec1, and mec2. The predicted amino acid sequence of Cdc44p contains GTPase consensus sites, and mutations in these regions cause a conditional cell cycle arrest. Taken together, these observations suggest that the essential CDC44 gene may encode the large subunit of yeast replication factor C.     

The RFC2 gene encoding a subunit of replication factor C of Saccharomyces cerevisiae.

Replication Factor C (RF-C) of Saccharomyces cerevisiae is a complex that consists of several different polypeptides ranging from 120- to 37 kDa (Yoder and Burgers, 1991; Fien and Stillman, 1992), similar to human RF-C. We have isolated a gene, RFC2, that appears to be a component of the yeast RF-C. The RFC2 gene is located on chromosome X of S. cerevisiae and is essential for cell growth. Disruption of the RFC2 gene led to a dumbbell-shaped terminal morphology, common to mutants having a defect in chromosomal DNA replication. The steady-state levels of RFC2 mRNA fluctuated less during the cell cycle than other genes involved in DNA replication. Nucleotide sequence of the gene revealed an open reading frame corresponding to a polypeptide with a calculated Mr of 39,716 and a high degree of amino acid sequence homology to the 37-kDa subunit of human RF-C. Polyclonal antibodies against bacterially expressed Rfc2 protein specifically reduced RF-C activity in the RF-C-dependent reaction catalyzed by yeast DNA polymerase III. Furthermore, the Rfc2 protein was copurified with RF-C activity throughout RF-C purification. These results strongly suggest that the RFC2 gene product is a component of yeast RF-C. The bacterially expressed Rfc2 protein preferentially bound to primed single-strand DNA and weakly to ATP.     

Cloning and nucleotide sequence of DNA mismatch repair gene PMS1 from Saccharomyces cerevisiae: homology of PMS1 to procaryotic MutL and HexB.

The PMS1 gene from Saccharomyces cerevisiae, implicated in DNA mismatch repair in yeast cells (M. S. Williamson, J. C. Game, and S. Fogel, Genetics 110:609-646, 1985), was cloned, and the nucleotide sequence was determined. The nucleotide sequence showed a 2,712-base-pair open reading frame; the predicted molecular mass of the deduced protein is 103 kilodaltons. Deletion mutants of the open reading frame were constructed and genetically characterized. The deduced amino acid sequence of the PMS1 gene exhibited homology to those of the mutL gene from Salmonella typhimurium and the hexB gene from Streptococcus pneumoniae, genes required for DNA mismatch repair in these organisms. The homology suggests an evolutionary relationship of DNA mismatch repair in procaryotes and eucaryotes.     

Isolation, sequencing and overexpression of the gene encoding the theta subunit of DNA polymerase III holoenzyme.

The gene encoding the theta subunit of DNA polymerase III holoenzyme, designated holE, was isolated using a strategy in which peptide sequence was used to derive a DNA hybridization probe. Sequencing of the gene, which maps to 41.43 centisomes of the chromosome, revealed a 76-codon open reading frame predicted to produce a protein of 8,846 Da. When placed in a tac promoter expression vector, the open reading frame directed expression of a protein, that comigrated with authentic theta subunit from purified holoenzyme, to 6% of total soluble protein.