Identification of two cell-cycle-controlling cdc2 gene homologs in Arabidopsis thaliana

The cdc2 gene product (p34cdc2) has been thought to play a central role in control of the mitotic cell cycle of yeasts and animals. To approach an understanding of the cell-cycle-control system in higher plants, we isolated, from an Arabidopsis thaliana cDNA library, two clones (CDC2a and CDC2b) similar to the Schizosaccharomyces pombe cdc2 gene. Genomic Southern-blot analysis with the CDC2a and CDC2b cDNA probes suggested that the A. thaliana genome contains several additional cdc2-like genes, which together with the CDC2a and CDC2b genes may constitute a CDC2 gene family. The CDC2a cDNA expressed in Sc. pombe corrected the elongated morphology, caused by the temperature-sensitive cdc2-33 mutation, to the normal shapes, indicating that the A. thaliana CDC2a gene product resembles Sc. pombe p34cdc2 functionally as well as structurally. These results support the view that the cell cycle of higher plants is controlled by an analogue of a p34cdc2-centered regulatory system like that of yeasts and animals.     

Cloning and characterization of the Saccharomyces cerevisiae CDC6 gene.

The yeast cell division cycle gene CDC6 was isolated by complementation of a temperature-sensitive cdc6 mutant with a genomic library. The amino acid sequence of the 48 kDalton CDC6 gene product, as deduced from DNA sequence data, includes the three consensus peptide motifs involved in guanine nucleotide binding and GTPase activity, a target site for cAMP-dependent protein kinase and a carboxy-terminal domain related to metallothionein sequences. A plasmid-encoded CDC6-beta-galactosidase hybrid protein was located at the plasma membrane by indirect immunofluorescence. Disruption experiments indicate that the CDC6 gene product is essential for mitotic growth.     

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.     

CDC55, a Saccharomyces cerevisiae gene involved in cellular morphogenesis: identification, characterization, and homology to the B subunit of mammalian type 2A protein phosphatase.

Microscopic screening of a collection of cold-sensitive mutants of Saccharomyces cerevisiae led to the identification of a new gene, CDC55, which appears to be involved in the morphogenetic events of the cell cycle. CDC55 maps between CDC43 and CHC1 on the left arm of chromosome VII. At restrictive temperature, the original cdc55 mutant produces abnormally elongated buds and displays a delay or partial block of septation and/or cell separation. A cdc55 deletion mutant displays a cold-sensitive phenotype like that of the original isolate. Sequencing of CDC55 revealed that it encodes a protein of about 60 kDa, as confirmed by Western immunoblots using Cdc55p-specific antibodies. This protein has greater than 50% sequence identity to the B subunits of rabbit skeletal muscle type 2A protein phosphatase; the latter sequences were obtained by analysis of peptides derived from the purified protein, a polymerase chain reaction product, and cDNA clones. An extragenic suppressor of the cdc55 mutation lies in BEM2, a gene previously identified on the basis of an apparent role in bud emergence.     

p62cdc23 of Saccharomyces cerevisiae: a nuclear tetratricopeptide repeat protein with two mutable domains.

CDC23 is required in Saccharomyces cerevisiae for cell cycle progression through the G2/M transition. The CDC23 gene product contains tandem, imperfect repeats, termed tetratricopeptide repeats, (TPR) units common to a protein family that includes several other nuclear division CDC genes. In this report we have used mutagenesis to probe the functional significance of the TPR units within CDC23. Analysis of truncated derivatives indicates that the TPR block of CDC23 is necessary for the function or stability of the polypeptide. In-frame deletion of a single TPR unit within the repeat block proved sufficient to inactivate CDC23 in vivo, though this allele could rescue the temperature-sensitive defect of a cdc23 point mutant by intragenic complementation. By both in vitro and in vivo mutagenesis techniques, 17 thermolabile cdc23 alleles were produced and examined. Fourteen alleles contained single amino acid changes that were found to cluster within two distinct mutable domains, one of which encompasses the most canonical TPR unit found in CDC23. In addition, we have characterized CDC23 as a 62-kDa protein (p62cdc23) that is localized to the yeast nucleus. Our mutagenesis results suggest that TPR blocks form an essential domain within members of the TPR family.     

An additional homolog of the fission yeast cdc25+ gene occurs in humans and is highly expressed in some cancer cells.

The gene cdc25+ is a mitotic inducer controlling transition from the G2 to the M phase of the cell cycle in the fission yeast, Schizosaccharomyces pombe. Using phenotypic complementation of a mutant of S. pombe, we have cloned a human homolog (CDC25Hu2) of the cdc25+ gene that differs markedly in structure from CDC25 (referred to here as CDC25Hu1), the first such homolog to be isolated. The carboxyl-terminal region of p63CDC25Hu2 shares significant sequence similarity with cdc25 protein homologs from other eukaryotes and possesses full complementation activity. CDC25Hu2 is expressed in human cell lines 10 to 100 times more than CDC25Hu1, and its expression is particularly high in some cancers, including SV40-transformed fibroblasts. Whereas CDC25Hu1 is predominantly expressed in G2, CDC25Hu2 is expressed throughout the cell cycle with a moderate increase in G2. Thus, at least two homologs of the cdc25 gene exist and are both expressed in human cells. The implications of CDC25Hu2 overexpression in some cancer cells are discussed.     

Isolation and nucleotide sequence of a Saccharomyces cerevisiae protein kinase gene suppressing the cell cycle start mutation cdc25

We have isolated two unlinked yeast genes complementing the cell division cycle mutant cdc25-1, one containing the wild type allele CDC25 and the other acting as an extragenic suppressor of the cdc25-1 lesion if present on a multicopy plasmid. Nucleotide sequence analysis of the suppressor gene has revealed an open reading frame that encodes a 45,000-dalton protein belonging to the protein kinase family. The cdc25-suppressing protein kinase (PK-25) shows 48% sequence similarity to the catalytic subunit (CA) of mammalian cAMP-dependent protein kinase and 27-31% similarity to cyclic nucleotide-independent enzymes, including the yeast CDC28 gene product. The PK-25 gene was targeted by integrative transformation into a chromosomal region unlinked to the CYR2 site, the structural gene of CA. The cdc25-suppressing protein kinase is also functionally different from CA, since cyr2 strains deficient in the free catalytic subunit remain temperature sensitive if transformed with a multicopy plasmid containing the PK-25 gene. Furthermore, a deficiency of the cAMP-binding regulatory subunit (RA) caused by the bcy1 mutation fails to suppress the cdc25 mutation, indicating that PK-25 does not interact with the cAMP receptor protein. Our data suggest that the cdc25 suppressor gene encodes a cAMP-independent protein kinase involved in the control of the cell cycle start.     

Cloning of Saccharomyces cerevisiae DNA replication genes: isolation of the CDC8 gene and two genes that compensate for the cdc8-1 mutation.

The CDC8 gene, whose product is required for DNA replication in Saccharomyces cerevisiae, has been isolated on recombinant plasmids. The yeast vector YCp50 bearing the yeast ARS1, CEN4, and URA3 sequences, to provide for replication, stability, and selection, respectively, was used to prepare a recombinant plasmid pool containing the entire yeast genome. Plasmids capable of complementing the temperature-sensitive cdc8-1 mutation were isolated by transformation of a cdc8-1 mutant and selection for clones able to grow at the nonpermissive temperature. The entire complementing activity is carried on a 0.75-kilobase fragment, as revealed by deletion mapping. This fragment lies 1 kilobase downstream from the well-characterized sup4 gene, a gene known to be genetically linked to CDC8, thus confirming that the cloned gene corresponds to the chromosomal CDC8 gene. Two additional recombinant plasmids that complement the cdc8-1 mutation but that do not contain the 0.75-kilobase fragment or any flanking DNA were also identified in this study. These plasmids may contain genes that compensate for the lack of CDC8 gene product.     

SDC25, a CDC25-like gene which contains a RAS-activating domain and is a dispensable gene of Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the CDC25 gene product activates adenylate cyclase through RAS1 and RAS2 gene products. We have recently described the cloning of a DNA fragment which suppresses the cdc25 mutation but not ras1, ras2, or cdc35 mutations. This fragment contains a 5'-truncated open reading frame which shares 47% identity with the C-terminal part of the CDC25 gene. We named the entire gene SDC25. In this paper, we report the cloning, sequencing, and characterization of the complete SDC25 gene. The SDC25 gene is located on the chromosome XII close to the centromere. It is transcribed into a 4-kb-long mRNA that contains an open reading frame of 1,251 codons. Homology with the CDC25 gene extends in the N-terminal part, although the degree of similarity is lower than in the C-terminal part. In contrast with the C-terminal part, the complete SDC25 gene was found not to suppress the CDC25 gene defect. A deletion in the N-terminal part restored the suppressing activity, a result which suggests the existence of a regulatory domain. The SDC25 gene was found to be dispensable for cell growth under usual conditions. No noticeable phenotype was found in the deleted strain.     

A region of proto-dbl essential for its transforming activity shows sequence similarity to a yeast cell cycle gene, CDC24, and the human breakpoint cluster gene, bcr

Proto-dbl is a human proto-oncogene, whose oncogenic activation was initially detected by DNA transfection. We report significant sequence similarity between the predicted proto-dbl product and the products of CDC24, a Saccharomyces cerevisiae cell division cycle gene required for correct budding and establishment of cell polarity, and bcr, a gene implicated in the pathogenesis of chronic myelogenous leukemia (CML). Of 925 residues of the predicted proto-dbl protein, a stretch of 238 residues showed 29% and 22% identity over a region of similar length of the CDC24 and bcr proteins, respectively. When evolutionarily conservative substitutions were taken into account, the similarities were 68.8% and 71.6% for proto-dbl/CDC24 and proto-dbl/bcr gene products, respectively. Moreover, all three sequences were predicted to be markedly hydrophilic over this region. Very small deletions within the conserved region completely abolished transforming activity of dbl, while extensive deletion outside of this region had no effect. Even substitutions over a small stretch of close similarity with the other proteins substantially impaired transforming activity. Cells transformed by the dbl oncogene, like cdc24 mutants arrested at the nonpermissive temperature, form multinucleate cells. Thus, our findings indicate that the conserved region is an essential domain that may reflect important functional similarities among these otherwise highly divergent molecules.     

A cDNA homologue of Schizosaccharomyces pombe cdc5(+) from the mushroom Lentinula edodes: characterization of the cDNA and its expressed product

A cDNA homologue of Schizosaccharomyces pombe cdc5(+) was isolated from the basidiomycete mushroom Lentinula edodes and it was named Le.cdc5 cDNA. The deduced Le.CDC5 (842 amino acid residues) possessed N-terminal amino acid sequence highly homologous to those of S. pombe cdc5(+) gene product (Sp.cdc5p) and Sp.cdc5p-related proteins (SPCDC5RPs). The N-terminal 185 amino acid peptide of Le.CDC5 (Le.CDC5(1-185) peptide) produced in Escherichia coli was subjected to random binding-site selection analysis, revealing that Le.CDC5(1-185) peptide binds to a 7-bp sequence with the consensus sequence of 5'GCAATGT3' (complementary; 5'ACATTGC3'). Genomic binding-site (GBS) cloning by using Le.CDC5(1-185) peptide resulted in an isolation of the DNA fragment that contained three sets of 7-bp consensus-like sequence and TATA box. The Le.CDC5 protein contained two putative phosphorylation sites of cAMP-dependent protein kinase (A kinase) in its C-terminus. There exists a possible leucine zipper between the two phosphorylation sites. The Le.CDC5 fragment containing the two phosphorylation sites was actually phosphorylated by commercially available A kinase. Yeast two-hybrid analysis suggested the homodimerization of Le.CDC5 protein probably through the leucine zipper. Northern blot analysis showed that Le.cdc5 gene is most actively transcribed in primordia and small immature fruiting bodies of L. edodes, implying that Le.cdc5 may play a role in the beginning and early stage of fruiting-body formation.     

Mutational analysis of CDC42Sc, a Saccharomyces cerevisiae gene that encodes a putative GTP-binding protein involved in the control of cell polarity.

The Saccharomyces cerevisiae CDC42 gene product, a member of the ras superfamily of low-molecular-weight GTP-binding proteins, is involved in the control of cell polarity. We have analyzed the effects of three CDC42 mutations (Gly to Val-12, Gln to Leu-61, and Asp to Ala-118) in the putative GTP-binding and hydrolysis domains and one mutation (Cys to Ser-188) in the putative isoprenylation site. The first three mutations resulted in either a dominant-lethal or dose-dependent dominant-lethal phenotype when present on plasmids in haploid cdc42-1ts or wild-type strains. Both wild-type and cdc42-1ts cells carrying plasmids (pGAL) with either the CDC42Val-12 or CDC42Leu-61 alleles under the control of a GAL promoter were arrested with a novel phenotype of large cells with elongated or multiple buds. Cells carrying pGAL-CDC42Ala-118 were arrested as large, round, unbudded cells reminiscent of cdc42-1ts arrested cells. The different phenotype of the CDC42Ala-118 mutant versus the CDC42Val-12 and CDC42Leu-61 mutants was unexpected since the phenotypes of all three analogous ras mutants were similar to each other. This suggests that aspects of the biochemical properties of the Cdc42 protein differ from those of the Ras protein. The cdc42Ser-188 mutant gene was incapable of complementing the cdc42-1ts mutation and was recessive to both wild-type and cdc42-1ts. In double-mutant alleles, the cdc42Ser-188 mutation was capable of suppressing the dominant lethality associated with the three putative GTP-binding and hydrolysis mutations, suggesting that isoprenylation is necessary for the activity of the wild-type and mutant proteins.     

Comparison of Thermosensitive Alleles of the Cdc25 Gene Involved in the Camp Metabolism of Saccharomyces Cerevisiae

The CDC25 gene from Saccharomyces cerevisiae is an essential component of the RAS-adenylate cyclase pathway. Genetic and biochemical evidence has led to the proposal that the gene product may act upstream of RAS, possibly as a guanine nucleotide exchange factor. We report here the cloning, sequencing and characterization of four mutations in the CDC25 gene. All four are missense mutations which reside within the carboxy-terminal quarter of the single open reading frame found within the gene. Three of the four are missense mutations in the same amino acid codon. A search of protein data bases reveals that the carboxy terminus of the putative CDC25 gene product is similar to that of LTE1, a gene required for growth at low temperature and SCD25, a suppressor of cdc25. Taken together these data indicate that the carboxy terminus of CDC25 plays a critical role in the function of the CDC25 gene product and that other proteins, such as LTE1 or SCD25, may have related activities.     

<Emphasis Type="Italic">STM1</Emphasis>, a gene which encodes a guanine quadruplex binding protein,interacts with<Emphasis Type="Italic"> CDC13</Emphasis> in<Emphasis Type="Italic"> Saccharomyces cerevisiae</Emphasis>

The CDC13 gene encodes a protein that binds to the G-rich single-strand at yeast telomeres, and serves as a regulator of telomere replication. Cdc13 interacts with Est1 and DNA polymerase alpha, and cells carrying the temperature-sensitive allele cdc13-1 cannot complete telomere replication at the restrictive temperature and possess long telomeres. We attempted to isolate and characterize genes that interact with CDC13, in order to clarify the molecular mechanisms of telomere replication. A STM1 cDNA was isolated in a two-hybrid screen using CDC13 as a bait. The temperature-sensitive growth phenotype and the alteration in telomere size in cdc13-1 cells were corrected by introduction of the STM1 gene on a multicopy vector, but the extended G-rich single-strand overhangs which are also characteristic in the cdc13-1 mutant were not affected. Furthermore, we found that multiple copies of SGS1, a gene encoding a helicase that can unwind guanine quadruplexes, inhibited suppression of the cdc13-1 phenotype by STM1. We also demonstrate that a fusion protein consisting of the N-terminal region of Cdc13 and the C-terminal region of Stm1 (which shows similarity to the beta-subunit of the telomere binding complex in Oxytricha) could complement a cdc13 disruptant. Although STM1 itself is not essential for telomere replication, our findings suggest that STM1 genetically interacts with CDC13 to maintain telomere structure.     

Genetic and Molecular Analysis of Cdr1/Nim1 in Schizosaccharomyces Pombe

The cdr1 gene in Schizosaccharomyces pombe was identified as a mutation affecting the nutritional responsiveness of the mitotic size control. cdr1 alleles have been further analyzed for genetic interactions with elements of the mitotic control pathway and cloned by plasmid rescue of a conditional lethal cdr1-76 cdc25-22 double mutant. These analyses show that the cdr1 gene is allelic to nim1, a gene identified as a high copy number plasmid suppressor of the mitotic control gene, cdc25. The gene structure for cdr1 differs from the described nim1 gene in the carboxyl-terminal portion of the gene. The published nim1 sequence encoded a product of predicted Mr 45,000, and included 356 amino acids from the amino-terminal region of the gene and 14 amino acids from a noncontiguous carboxyl-terminal fragment. The cdr1 sequence includes an additional 237 amino acids of the contiguous fragment and encodes a product of predicted Mr 67,000. The sequence shows a high level of identity with protein kinases over the amino-terminal catalytic domain, and limited identity with yeast protein kinases SNF1, KIN2 and KIN1 over part of the carboxyl-terminal domain. The effect of overexpression of the full length gene has been examined in various genetic backgrounds. These data show that the full length gene product is required to give a normal cell cycle response to nitrogen starvation. A detailed examination of the genetic interaction of cdr1 mutants with various mutants of mitotic control genes (cdc2, cdc25, wee1, cdc13) demonstrated strong interactions with cdc25, some cdc2 alleles, and with cdc13-117. Overall, the results are interpretable within the framework of the existing model of cdr1/nim1 action in mitotic control, i.e., cdr1 functions upstream of wee1 to relieve mitotic inhibition.     

Isolation of a CDC28 homologue from Cryptococcus neoformans that is able to complement cdc28 temperature-sensitive mutants of Saccharomyces cerevisiae

A partial cDNA fragment of the Cryptococcus neoformans homologue of the main cell cycle control gene CDC28/cdc2 was isolated using degenerate primer RT-PCR. A subsequent search in the C. neoformans genome database identified several sequences similar to CDC28/cdc2. A part of the sequence which showed the highest similarity to CDC28/cdc2 turned out to be identical to the partial cyclin-dependent kinase (Cdk) cDNA fragment isolated by degenerate RT-PCR. The full-length coding region of this Cdk homologue was amplified by RT-PCR using primers designed to target regions around start and stop codons, and the gene was named CnCdk1. To determine its function, an analysis of deduced amino acid sequence of the CnCdk1 was performed and its ability to rescue Saccharomyces cerevisiae cdc28-temperature sensitive mutants was tested. S. cerevisiae cdc28-4 and cdc28-1N strains transformed with the pYES2- CnCdk1 construct exhibited growth at 36.5 degrees C in galactose-raffinose medium, but not in glucose medium. Results of the sequence analysis and the fact that CnCdk1 is able to complement the S. cerevisiae cdc28-ts mutation support its assumed role as the CDC28/cdc2 homologue in C. neoformans.     

The cdc30 mutation in Saccharomyces cerevisiae results in a temperature-sensitive isoenzyme of phosphoglucose isomerase

The cdc30 mutation in the yeast Saccharomyces cerevisiae causes cell cycle arrest late in nuclear division when cells are shifted from the permissive temperature of 25 degrees C to the restrictive temperature of 36.5 degrees C. Cell cycle arrest at 36.5 degrees C is dependent upon the carbon source used: a shift-up in glucose containing media results in cell cycle blockade, whereas a shift-up in ethanol, fructose, glycerol, glycerol plus ethanol, or mannose does not. Metabolite analyses showed accumulation of glucose 6-phosphate in a cdc30-bearing strain after a temperature shift-up in glucose-containing medium. Thermal denaturation studies and kinetic measurements indicate the existence of two isoenzymes of phosphoglucose isomerase (EC 5.3.1.9); one of which is apparently altered in the temperature-sensitive cell cycle mutant. We propose that the gene products of both the CDC30 and PG11 genes are required for cell cycle progression in glucose media and that the PGI1 gene product has a regulatory function over the CDC30 gene product.